Semi-synthetic complex derived from nucleic-acid free viral particles. They are essentially reconstituted viral coats, where the infectious nucleocapsid is replaced by a compound of choice. Virosomes retain their fusogenic activity and thus deliver the incorporated compound (antigens, drugs, genes) inside the target cell. They can be used for vaccines (VACCINES, VIROSOME), drug delivery, or gene transfer.
Vaccines using VIROSOMES as the antigen delivery system that stimulates the desired immune response.
Suspensions of killed or attenuated microorganisms (bacteria, viruses, fungi, protozoa), antigenic proteins, synthetic constructs, or other bio-molecular derivatives, administered for the prevention, amelioration, or treatment of infectious and other diseases.
Vaccines in which the infectious microbial nucleic acid components have been destroyed by chemical or physical treatment (e.g., formalin, beta-propiolactone, gamma radiation) without affecting the antigenicity or immunogenicity of the viral coat or bacterial outer membrane proteins.
Suspensions of attenuated or killed viruses administered for the prevention or treatment of infectious viral disease.
Two or more vaccines in a single dosage form.
Recombinant DNA vectors encoding antigens administered for the prevention or treatment of disease. The host cells take up the DNA, express the antigen, and present it to the immune system in a manner similar to that which would occur during natural infection. This induces humoral and cellular immune responses against the encoded antigens. The vector is called naked DNA because there is no need for complex formulations or delivery agents; the plasmid is injected in saline or other buffers.
Small synthetic peptides that mimic surface antigens of pathogens and are immunogenic, or vaccines manufactured with the aid of recombinant DNA techniques. The latter vaccines may also be whole viruses whose nucleic acids have been modified.
Suspensions of attenuated or killed bacteria administered for the prevention or treatment of infectious bacterial disease.
Vaccines or candidate vaccines containing inactivated HIV or some of its component antigens and designed to prevent or treat AIDS. Some vaccines containing antigens are recombinantly produced.
Vaccines consisting of one or more antigens that stimulate a strong immune response. They are purified from microorganisms or produced by recombinant DNA techniques, or they can be chemically synthesized peptides.
Semisynthetic vaccines consisting of polysaccharide antigens from microorganisms attached to protein carrier molecules. The carrier protein is recognized by macrophages and T-cells thus enhancing immunity. Conjugate vaccines induce antibody formation in people not responsive to polysaccharide alone, induce higher levels of antibody, and show a booster response on repeated injection.
Administration of vaccines to stimulate the host's immune response. This includes any preparation intended for active immunological prophylaxis.
Vaccines made from antigens arising from any of the four strains of Plasmodium which cause malaria in humans, or from P. berghei which causes malaria in rodents.
Vaccines or candidate vaccines used to prevent PAPILLOMAVIRUS INFECTIONS. Human vaccines are intended to reduce the incidence of UTERINE CERVICAL NEOPLASMS, so they are sometimes considered a type of CANCER VACCINES. They are often composed of CAPSID PROTEINS, especially L1 protein, from various types of ALPHAPAPILLOMAVIRUS.
Vaccines or candidate vaccines used to prevent infection with NEISSERIA MENINGITIDIS.
Vaccines or candidate vaccines containing inactivated hepatitis B or some of its component antigens and designed to prevent hepatitis B. Some vaccines may be recombinantly produced.
A live attenuated virus vaccine of chick embryo origin, used for routine immunization of children and for immunization of adolescents and adults who have not had measles or been immunized with live measles vaccine and have no serum antibodies against measles. Children are usually immunized with measles-mumps-rubella combination vaccine. (From Dorland, 28th ed)
A suspension of killed Bordetella pertussis organisms, used for immunization against pertussis (WHOOPING COUGH). It is generally used in a mixture with diphtheria and tetanus toxoids (DTP). There is an acellular pertussis vaccine prepared from the purified antigenic components of Bordetella pertussis, which causes fewer adverse reactions than whole-cell vaccine and, like the whole-cell vaccine, is generally used in a mixture with diphtheria and tetanus toxoids. (From Dorland, 28th ed)
Vaccines or candidate vaccines containing antigenic polysaccharides from Haemophilus influenzae and designed to prevent infection. The vaccine can contain the polysaccharides alone or more frequently polysaccharides conjugated to carrier molecules. It is also seen as a combined vaccine with diphtheria-tetanus-pertussis vaccine.
An active immunizing agent and a viable avirulent attenuated strain of Mycobacterium tuberculosis, var. bovis, which confers immunity to mycobacterial infections. It is used also in immunotherapy of neoplasms due to its stimulation of antibodies and non-specific immunity.
A suspension of formalin-inactivated poliovirus grown in monkey kidney cell tissue culture and used to prevent POLIOMYELITIS.
Vaccines or candidate vaccines used to prevent and treat RABIES. The inactivated virus vaccine is used for preexposure immunization to persons at high risk of exposure, and in conjunction with rabies immunoglobulin, for postexposure prophylaxis.
Vaccines or candidate vaccines used to prevent infection with ROTAVIRUS.
Vaccines or candidate vaccines used to prevent infection with VIBRIO CHOLERAE. The original cholera vaccine consisted of killed bacteria, but other kinds of vaccines now exist.
Vaccines used to prevent TYPHOID FEVER and/or PARATYPHOID FEVER which are caused by various species of SALMONELLA. Attenuated, subunit, and inactivated forms of the vaccines exist.
A live VACCINIA VIRUS vaccine of calf lymph or chick embryo origin, used for immunization against smallpox. It is now recommended only for laboratory workers exposed to smallpox virus. Certain countries continue to vaccinate those in the military service. Complications that result from smallpox vaccination include vaccinia, secondary bacterial infections, and encephalomyelitis. (Dorland, 28th ed)
Vaccines or candidate vaccines used to prevent or treat TUBERCULOSIS.
Immunoglobulins produced in response to VIRAL ANTIGENS.
A live, attenuated varicella virus vaccine used for immunization against chickenpox. It is recommended for children between the ages of 12 months and 13 years.
A vaccine consisting of DIPHTHERIA TOXOID; TETANUS TOXOID; and whole-cell PERTUSSIS VACCINE. The vaccine protects against diphtheria, tetanus, and whooping cough.
Vaccines used to prevent infection by MUMPS VIRUS. Best known is the live attenuated virus vaccine of chick embryo origin, used for routine immunization of children and for immunization of adolescents and adults who have not had mumps or been immunized with live mumps vaccine. Children are usually immunized with measles-mumps-rubella combination vaccine.
Vaccines or candidate vaccines used to prevent infection with hepatitis A virus (HEPATOVIRUS).
Schedule giving optimum times usually for primary and/or secondary immunization.
Substances that augment, stimulate, activate, potentiate, or modulate the immune response at either the cellular or humoral level. The classical agents (Freund's adjuvant, BCG, Corynebacterium parvum, et al.) contain bacterial antigens. Some are endogenous (e.g., histamine, interferon, transfer factor, tuftsin, interleukin-1). Their mode of action is either non-specific, resulting in increased immune responsiveness to a wide variety of antigens, or antigen-specific, i.e., affecting a restricted type of immune response to a narrow group of antigens. The therapeutic efficacy of many biological response modifiers is related to their antigen-specific immunoadjuvanticity.
Any immunization following a primary immunization and involving exposure to the same or a closely related antigen.
A combined vaccine used to prevent MEASLES; MUMPS; and RUBELLA.
Vaccines or candidate vaccines used to prevent STREPTOCOCCAL INFECTIONS.
Vaccines or candidate vaccines used to prevent ANTHRAX.
Vaccines or candidate vaccines used to prevent infection with DENGUE VIRUS. These include live-attenuated, subunit, DNA, and inactivated vaccines.
Deliberate stimulation of the host's immune response. ACTIVE IMMUNIZATION involves administration of ANTIGENS or IMMUNOLOGIC ADJUVANTS. PASSIVE IMMUNIZATION involves administration of IMMUNE SERA or LYMPHOCYTES or their extracts (e.g., transfer factor, immune RNA) or transplantation of immunocompetent cell producing tissue (thymus or bone marrow).
Any vaccine raised against any virus or viral derivative that causes hepatitis.
A live vaccine containing attenuated poliovirus, types I, II, and III, grown in monkey kidney cell tissue culture, used for routine immunization of children against polio. This vaccine induces long-lasting intestinal and humoral immunity. Killed vaccine induces only humoral immunity. Oral poliovirus vaccine should not be administered to immunocompromised individuals or their household contacts. (Dorland, 28th ed)
Vaccine used to prevent YELLOW FEVER. It consists of a live attenuated 17D strain of the YELLOW FEVER VIRUS.
Immunoglobulins produced in a response to BACTERIAL ANTIGENS.
A suspension of killed Yersinia pestis used for immunizing people in enzootic plague areas.
Suspensions of attenuated or killed fungi administered for the prevention or treatment of infectious fungal disease.
A live attenuated virus vaccine of duck embryo or human diploid cell tissue culture origin, used for routine immunization of children and for immunization of nonpregnant adolescent and adult females of childbearing age who are unimmunized and do not have serum antibodies to rubella. Children are usually immunized with measles-mumps-rubella combination vaccine. (Dorland, 28th ed)
Vaccines that are produced by using only the antigenic part of the disease causing organism. They often require a "booster" every few years to maintain their effectiveness.
Vaccines or candidate vaccines designed to prevent SAIDS; (SIMIAN ACQUIRED IMMUNODEFICIENCY SYNDROME); and containing inactivated SIMIAN IMMUNODEFICIENCY VIRUS or type D retroviruses or some of their component antigens.
Vaccines or candidate vaccines used to prevent infection with SALMONELLA. This includes vaccines used to prevent TYPHOID FEVER or PARATYPHOID FEVER; (TYPHOID-PARATYPHOID VACCINES), and vaccines used to prevent nontyphoid salmonellosis.
Vaccines using supra-molecular structures composed of multiple copies of recombinantly expressed viral structural proteins. They are often antigentically indistinguishable from the virus from which they were derived.
Inbred BALB/c mice are a strain of laboratory mice that have been selectively bred to be genetically identical to each other, making them useful for scientific research and experiments due to their consistent genetic background and predictable responses to various stimuli or treatments.
Vaccines or candidate vaccines used to prevent EBOLA HEMORRHAGIC FEVER.
An acute viral infection in humans involving the respiratory tract. It is marked by inflammation of the NASAL MUCOSA; the PHARYNX; and conjunctiva, and by headache and severe, often generalized, myalgia.
Antibodies that reduce or abolish some biological activity of a soluble antigen or infectious agent, usually a virus.
Staphylococcal vaccines are prophylactic agents developed to prevent infections caused by Staphylococcus aureus, a pathogenic bacterium that frequently colonizes human skin and mucous membranes, often targeting surface proteins or toxins for immune response induction.
Combined vaccines consisting of DIPHTHERIA TOXOID; TETANUS TOXOID; and an acellular form of PERTUSSIS VACCINE. At least five different purified antigens of B. pertussis have been used in various combinations in these vaccines.
Vaccines or candidate vaccines used to prevent infection with CYTOMEGALOVIRUS.
Organized services to administer immunization procedures in the prevention of various diseases. The programs are made available over a wide range of sites: schools, hospitals, public health agencies, voluntary health agencies, etc. They are administered to an equally wide range of population groups or on various administrative levels: community, municipal, state, national, international.
Forceful administration into a muscle of liquid medication, nutrient, or other fluid through a hollow needle piercing the muscle and any tissue covering it.
A combined vaccine used to prevent infection with diphtheria and tetanus toxoid. This is used in place of DTP vaccine (DIPHTHERIA-TETANUS-PERTUSSIS VACCINE) when PERTUSSIS VACCINE is contraindicated.
Vaccines used to prevent POLIOMYELITIS. They include inactivated (POLIOVIRUS VACCINE, INACTIVATED) and oral vaccines (POLIOVIRUS VACCINE, ORAL).
Delivery of medications through the nasal mucosa.
Vaccines or candidate vaccines used to prevent or treat both enterotoxigenic and enteropathogenic Escherichia coli infections.
The major immunoglobulin isotype class in normal human serum. There are several isotype subclasses of IgG, for example, IgG1, IgG2A, and IgG2B.
Vaccines or candidate vaccines used to prevent infection with WEST NILE VIRUS.
Serologic tests in which a known quantity of antigen is added to the serum prior to the addition of a red cell suspension. Reaction result is expressed as the smallest amount of antigen which causes complete inhibition of hemagglutination.
Vaccines or candidate vaccines used to prevent bacillary dysentery (DYSENTERY, BACILLARY) caused by species of SHIGELLA.
The measurement of infection-blocking titer of ANTISERA by testing a series of dilutions for a given virus-antiserum interaction end-point, which is generally the dilution at which tissue cultures inoculated with the serum-virus mixtures demonstrate cytopathology (CPE) or the dilution at which 50% of test animals injected with serum-virus mixtures show infectivity (ID50) or die (LD50).
The production of ANTIBODIES by proliferating and differentiated B-LYMPHOCYTES under stimulation by ANTIGENS.
An attenuated vaccine used to prevent and/or treat HERPES ZOSTER, a disease caused by HUMAN HERPESVIRUS 3.
Sorbitan mono-9-octadecanoate poly(oxy-1,2-ethanediyl) derivatives; complex mixtures of polyoxyethylene ethers used as emulsifiers or dispersing agents in pharmaceuticals.
Antibody-mediated immune response. Humoral immunity is brought about by ANTIBODY FORMATION, resulting from TH2 CELLS activating B-LYMPHOCYTES, followed by COMPLEMENT ACTIVATION.
A bacterial vaccine for the prevention of brucellosis in man and animal. Brucella abortus vaccine is used for the immunization of cattle, sheep, and goats.
Tetanus toxoid is a purified and chemically inactivated form of the tetanus toxin, used as a vaccine to induce active immunity against tetanus disease by stimulating the production of antibodies.
Vaccines or candidate vaccines used to prevent infection by any virus from the family HERPESVIRIDAE.
The forcing into the skin of liquid medication, nutrient, or other fluid through a hollow needle, piercing the top skin layer.
Vaccines or candidate vaccines used to prevent infection with LEISHMANIA.
A compound with many biomedical applications: as a gastric antacid, an antiperspirant, in dentifrices, as an emulsifier, as an adjuvant in bacterins and vaccines, in water purification, etc.
A subtype of INFLUENZA A VIRUS with the surface proteins hemagglutinin 1 and neuraminidase 1. The H1N1 subtype was responsible for the Spanish flu pandemic of 1918.
Aluminum metal sulfate compounds used medically as astringents and for many industrial purposes. They are used in veterinary medicine for the treatment of ulcerative stomatitis, leukorrhea, conjunctivitis, pharyngitis, metritis, and minor wounds.

In vitro studies of core peptide-bearing immunopotentiating reconstituted influenza virosomes as a non-live prototype vaccine against hepatitis C virus. (1/62)

Evidence from both animal and human viral diseases indicate that cytotoxic T lymphocytes (CTL) are crucial in antiviral defense. However, a major problem to generate cytotoxic immunity is that in vivo exogenous antigens are usually presented via MHC class II pathway and normally fail to induce CTL. The aim of this study is to describe a novel non-live prototype vaccine based on immunopotentiating reconstituted influenza virosomes (IRIV) as vehicles to deliver HLA-A*0201-restricted hepatitis C virus (HCV) peptides (core 35-44 and 131-140) into the cytoplasm of at least three different target cell types [including T2, a transporter associated with antigen processing (TAP)-deficient cell line] resulting in MHC class I peptide presentation and lysis by peptide-specific CTL lines. Comparison of kinetics and analysis of the influence of peptide-stripping and Brefeldin A (BFA) reveal that there exists an endogenous, TAP-independent and BFA-sensitive pathway for virosomally delivered peptides. Moreover, virosomes containing influenza matrix peptide 58-66 can efficiently re-stimulate in vivo primed CTL and, importantly, IRIV containing HCV core peptides can even prime CTL from peripheral blood mononuclear cells of HCV(-) healthy blood donors in vitro. The fact that in vitro primed CTL are also able to specifically lyse target cells infected with recombinant vaccinia virus encoding the HCV core protein is of great importance for future studies based on in vivo mouse models. One of the most evident advantages of the virosomes in vivo will be their capability to protect the incorporated peptide from a large variety of degrading proteases.  (+info)

Efficacy of intranasal virosomal influenza vaccine in the prevention of recurrent acute otitis media in children. (2/62)

To evaluate the efficacy of an intranasal, inactivated, virosomal subunit influenza vaccine for prevention of new episodes of acute otitis media (AOM) in children with recurrent AOM, 133 children aged 1-5 years were randomized to receive the vaccine (n=67) or no vaccination (n=66). During a 6-month period, 24 (35.8%) vaccine recipients had 32 episodes of AOM; 42 (63.6%) control subjects had 64 episodes. The overall efficacy of vaccination in preventing AOM was 43.7% (95% confidence interval, 18.6-61.1; P=.002). Children vaccinated before influenza season had a significantly better outcome than did those vaccinated after the onset of influenza season. The cumulative duration of middle ear effusion was significantly less in vaccinated children than in control subjects. Data suggest that the intranasal virosomal influenza vaccine might be considered among the options for the prevention of AOM in children <5 years old with recurrent AOM.  (+info)

Induction of parasite growth-inhibitory antibodies by a virosomal formulation of a peptidomimetic of loop I from domain III of Plasmodium falciparum apical membrane antigen 1. (3/62)

Apical membrane antigen 1 (AMA-1) of Plasmodium falciparum is a leading candidate antigen for inclusion in a malaria subunit vaccine. Its ectodomain can be divided into three subdomains, each with disulfide bond-stabilized structures. Since the majority of antibodies raised against the ectodomain appear to recognize strain-specific epitopes in domain I, we attempted to develop a vaccine formulation which directs the immune response to a region that contains more conserved epitopes. Here we demonstrate that a virosomal formulation of a peptide that mimics the semiconserved loop I of domain III elicits parasite growth-inhibitory antibodies. A synthetic peptide comprising residues 446 to 490 of AMA-1 (AMA-1(446-490)) was conjugated through the N terminus to a derivative of phosphatidylethanolamine and the phosphatidylethanolamine-peptide conjugate was incorporated into immunopotentiating reconstituted influenza virosomes as a human-compatible antigen delivery system. Both cyclized and linear versions of the peptide antigen elicited antibodies which specifically bound to parasite-expressed AMA-1 in Western blotting with parasite lysates as well as in immunofluorescence assays with blood stage parasites. All 11 peptidomimetic-specific monoclonal antibodies generated were cross-reactive with parasite-expressed AMA-1. Antigen binding assays with a library of overlapping cyclic peptides covering the target sequence revealed differences in the fine specificity of these monoclonal antibodies and provided evidence that at least some of them recognized discontinuous epitopes. The two immunodominant epitopes comprised the conserved linear sequences K(459)RIKLN(464) and D(467)DEGNKKII(475). A key feature of the synthetic vaccine formulation proposed here is the display of the peptide antigen in a native-like state on the surface of the virosome.  (+info)

Successful booster antibody response up to 54 months after single primary vaccination with virosome-formulated, aluminum-free hepatitis A vaccine. (4/62)

This study demonstrates that a booster dose of the virosome-formulated, aluminum-free hepatitis A vaccine Epaxal (Berna Biotech) is highly immunogenic in subjects who received a single primary dose of this vaccine 18-54 months earlier. There were no significant differences in geometric mean antibody titers (GMTs) among subjects who received the booster dose 18-29 months (GMT, 2330 mIU/mL), 30-41 months (GMT, 2395 mIU/mL), or 42-54 months (GMT, 2432 mIU/mL) after primary vaccination, indicating that delays in the administration of booster vaccination do not lead to a loss of immunogenicity.  (+info)

Peptide-loaded chimeric influenza virosomes for efficient in vivo induction of cytotoxic T cells. (5/62)

Virus-specific CD8(+) T cells are thought to play an important role in resolving acute hepatitis C virus (HCV) infection as viral clearance has been associated with a strong and sustained CD8(+) T cell response. During the chronic state of HCV infection virus-specific T cells have a low frequency and a reduced responsiveness. Based on this, a therapeutic vaccine increasing the frequency of specific T cells is a promising alternative for the treatment of chronic HCV infection. We improved an existing vaccine platform based on immunopotentiating reconstituted influenza virosomes (IRIVs) for efficient delivery of peptide epitopes to the MHC class I antigen presentation pathway. IRIVs are proteoliposomes composed of phospholipids and influenza surface glycoproteins. Due to their fusogenic activity, IRIVs are able to deliver encapsulated macromolecules, e.g. peptides to immunocompetent cells. We developed a novel method based on chimeric virosomes [chimeric immunopotentiating reconstituted influenza virosomes (CIRIVs)] combining the high peptide-encapsulation capacity of liposomes and the fusion activity of virosomes. This new approach resulted in a 30-fold increase of the amount of incorporated soluble peptide compared with current preparation methods. To study the immunogenicity of chimeric virosomes HLA-A2.1 transgenic mice were immunized with CIRIVs containing the HCV Core132 peptide. Core132-CIRIVs efficiently induced specific cytotoxic and IFNgamma-producing T cells already with low peptide doses. Vaccine formulations, which include combinations of different HCV-derived CTL epitopes could be used to induce not only a strong but also a multi-specific CTL response, making them potential candidates for therapeutic and maybe prophylactic T cell vaccines in humans.  (+info)

Immune-reconstituted influenza virosome containing CD40L gene enhances the immunological and protective activity of a carcinoembryonic antigen anticancer vaccine. (6/62)

The correct interaction of a costimulatory molecule such as CD40L with its contrareceptor CD40 expressed on the membrane of professional APCs, provides transmembrane signaling that leads to APC activation. This process can be exploited to significantly improve the efficacy of cancer vaccines and the outcome of a possible cancer vaccine-induced, Ag-specific CTL response. Therefore, we investigated whether a novel intranasal delivery of immune-reconstituted influenza virosomes (IRIV), assembled with the CD40L gene (CD40L/IRIV), could be used to improve protective immunity and the Ag-specific CTL response against carcinoembryonic Ag (CEA) generated with a novel vaccine constituted of IRIV assembled with the CEA gene (CEA/IRIV). Our results suggest that CD40L/IRIV was able to augment CEA-specific CTL activity and CEA-specific protective immunity induced by CEA/IRIV most likely through the induction of a CTL response associated with a Th1 phenotype. In conclusion, we provide evidence that CD40L/IRIV, by acting through the CD40L/CD40 signaling pathway, acts as an immune-adjuvant that could increase the efficacy of a CEA-specific cancer vaccine, which could provide an efficacious new strategy for cancer therapy.  (+info)

A papillomavirus-like particle (VLP) vaccine displaying HPV16 L2 epitopes induces cross-neutralizing antibodies to HPV11. (7/62)

Peptides of the papillomavirus L2 minor capsid protein can induce antibodies (Ab) that neutralize a broad range of human papillomavirus (HPV) genotypes. Unfortunately, L2 is antigenically subdominant to L1 in the virus capsid. To induce a strong anti-L2 Ab response with cross-neutralizing activity to other mucosal types, chimeric virus-like particles (VLP) were generated in which HPV16 L2 neutralization epitopes (comprising L2 residues 69-81 or 108-120) are inserted within an immunodominant surface loop (between residues 133 and 134) of the L1 major capsid protein of bovine papillomavirus type 1 (BPV1). These chimeras self-assembled into pentameric capsomers, or complete VLP similar to wild type (wt) L1 protein. Immunization of rabbits with assembled particle preparations induced L2-specific serum Ab with titers 10-fold higher than those induced by cognate synthetic L2 peptides coupled to KLH. Antisera to both chimeric proteins partially neutralized HPV16 pseudovirions, confirming that both HPV16 L2 peptides define neutralization epitopes. When analyzed for the ability to cross-neutralize infection by authentic HPV11 virions, using detection of early viral RNA by RT-PCR-assays as the readout, immune serum to chimeric protein comprising L2 residues 69-81, but not 108-120, was partially neutralizing. In addition, mouse-antiserum induced by vaccinations with synthetic L2 peptide 108-120, but not 69-81, was partially neutralizing in this assay. Induction of cross-neutralization Ab by L2 epitopes displayed on chimeric VLP represents a possible strategy for the generation of broad-spectrum vaccines to protect against relevant mucosal HPV and associated neoplasia.  (+info)

Cost-effectiveness of adjuvanted influenza vaccination of healthy children 6 to 60 months of age. (8/62)

This study estimated the health and economic outcomes of universal administration of a adjuvanted influenza vaccine to healthy preschool children, as compared with current immunization practice. A Markov model simulated a cohort of 3 million children and their households undergoing five influenza seasons. Assuming a vaccine uptake rate of 30%, at the current acquisition cost of Euro 5.50 per vaccine dose influenza vaccination (two doses for unprimed children) of 6- to 60-month- (5-year) old children averted more than 1 million clinical influenza episodes and saved Euro 63 million, from the perspective of the Italian society. From the perspective of the Italian health care service, influenza vaccination of 6- to 60- and of 6- to 24-month-old children cost Euro 10,000 and Euro 13,333 per quality-adjusted life year (QALY) saved, respectively. Administration of a adjuvanted influenza vaccine to children aged 6 to 60 months was highly cost-effective for the health care service and cost saving for the society.  (+info)

Virosomes are artificially created structures that consist of viral envelopes, which have been stripped of their genetic material, combined with liposomes. They maintain the ability to fuse with cell membranes and can be used as delivery systems for vaccines or drugs, as they can carry foreign proteins or nucleic acids into cells. This makes them useful in the development of novel vaccine strategies and targeted therapy.

Virosomes are artificially constructed spherical vesicles composed of lipids and viral envelope proteins. They are used as a delivery system for vaccines and other therapeutic agents. In the context of vaccines, virosomes can be used to present viral antigens to the immune system in a way that mimics a natural infection, thereby inducing a strong immune response.

Virosome-based vaccines have several advantages over traditional vaccines. For example, they are non-infectious, meaning they do not contain live or attenuated viruses, which makes them safer for certain populations such as immunocompromised individuals. Additionally, virosomes can be engineered to target specific cells in the body, leading to more efficient uptake and presentation of antigens to the immune system.

Virosome-based vaccines have been developed for a variety of diseases, including influenza, hepatitis A, and HIV. While they are not yet widely used, they show promise as a safe and effective alternative to traditional vaccine approaches.

A vaccine is a biological preparation that provides active acquired immunity to a particular infectious disease. It typically contains an agent that resembles the disease-causing microorganism and is often made from weakened or killed forms of the microbe, its toxins, or one of its surface proteins. The agent stimulates the body's immune system to recognize the agent as a threat, destroy it, and "remember" it, so that the immune system can more easily recognize and destroy any of these microorganisms that it encounters in the future.

Vaccines can be prophylactic (to prevent or ameliorate the effects of a future infection by a natural or "wild" pathogen), or therapeutic (to fight disease that is already present). The administration of vaccines is called vaccination. Vaccinations are generally administered through needle injections, but can also be administered by mouth or sprayed into the nose.

The term "vaccine" comes from Edward Jenner's 1796 use of cowpox to create immunity to smallpox. The first successful vaccine was developed in 1796 by Edward Jenner, who showed that milkmaids who had contracted cowpox did not get smallpox. He reasoned that exposure to cowpox protected against smallpox and tested his theory by injecting a boy with pus from a cowpox sore and then exposing him to smallpox, which the boy did not contract. The word "vaccine" is derived from Variolae vaccinae (smallpox of the cow), the term devised by Jenner to denote cowpox. He used it in 1798 during a conversation with a fellow physician and later in the title of his 1801 Inquiry.

Inactivated vaccines, also known as killed or non-live vaccines, are created by using a version of the virus or bacteria that has been grown in a laboratory and then killed or inactivated with chemicals, heat, or radiation. This process renders the organism unable to cause disease, but still capable of stimulating an immune response when introduced into the body.

Inactivated vaccines are generally considered safer than live attenuated vaccines since they cannot revert back to a virulent form and cause illness. However, they may require multiple doses or booster shots to maintain immunity because the immune response generated by inactivated vaccines is not as robust as that produced by live vaccines. Examples of inactivated vaccines include those for hepatitis A, rabies, and influenza (inactivated flu vaccine).

A viral vaccine is a biological preparation that introduces your body to a specific virus in a way that helps your immune system build up protection against the virus without causing the illness. Viral vaccines can be made from weakened or inactivated forms of the virus, or parts of the virus such as proteins or sugars. Once introduced to the body, the immune system recognizes the virus as foreign and produces an immune response, including the production of antibodies. These antibodies remain in the body and provide immunity against future infection with that specific virus.

Viral vaccines are important tools for preventing infectious diseases caused by viruses, such as influenza, measles, mumps, rubella, polio, hepatitis A and B, rabies, rotavirus, chickenpox, shingles, and some types of cancer. Vaccination programs have led to the control or elimination of many infectious diseases that were once common.

It's important to note that viral vaccines are not effective against bacterial infections, and separate vaccines must be developed for each type of virus. Additionally, because viruses can mutate over time, it is necessary to update some viral vaccines periodically to ensure continued protection.

Combined vaccines are defined in medical terms as vaccines that contain two or more antigens from different diseases, which are given to provide protection against multiple diseases at the same time. This approach reduces the number of injections required and simplifies the immunization schedule, especially during early childhood. Examples of combined vaccines include:

1. DTaP-Hib-IPV (e.g., Pentacel): A vaccine that combines diphtheria, tetanus, pertussis (whooping cough), Haemophilus influenzae type b (Hib) disease, and poliovirus components in one injection to protect against these five diseases.
2. MMRV (e.g., ProQuad): A vaccine that combines measles, mumps, rubella, and varicella (chickenpox) antigens in a single injection to provide immunity against all four diseases.
3. HepA-HepB (e.g., Twinrix): A vaccine that combines hepatitis A and hepatitis B antigens in one injection, providing protection against both types of hepatitis.
4. MenACWY-TT (e.g., MenQuadfi): A vaccine that combines four serogroups of meningococcal bacteria (A, C, W, Y) with tetanus toxoid as a carrier protein in one injection for the prevention of invasive meningococcal disease caused by these serogroups.
5. PCV13-PPSV23 (e.g., Vaxneuvance): A vaccine that combines 13 pneumococcal serotypes with PPSV23, providing protection against a broader range of pneumococcal diseases in adults aged 18 years and older.

Combined vaccines have been thoroughly tested for safety and efficacy to ensure they provide a strong immune response and an acceptable safety profile. They are essential tools in preventing various infectious diseases and improving overall public health.

I could not find a specific medical definition for "Vaccines, DNA." However, I can provide you with some information about DNA vaccines.

DNA vaccines are a type of vaccine that uses genetically engineered DNA to stimulate an immune response in the body. They work by introducing a small piece of DNA into the body that contains the genetic code for a specific antigen (a substance that triggers an immune response). The cells of the body then use this DNA to produce the antigen, which prompts the immune system to recognize and attack it.

DNA vaccines have several advantages over traditional vaccines. They are relatively easy to produce, can be stored at room temperature, and can be designed to protect against a wide range of diseases. Additionally, because they use DNA to stimulate an immune response, DNA vaccines do not require the growth and culture of viruses or bacteria, which can make them safer than traditional vaccines.

DNA vaccines are still in the experimental stages, and more research is needed to determine their safety and effectiveness. However, they have shown promise in animal studies and are being investigated as a potential tool for preventing a variety of infectious diseases, including influenza, HIV, and cancer.

Synthetic vaccines are artificially produced, designed to stimulate an immune response and provide protection against specific diseases. Unlike traditional vaccines that are derived from weakened or killed pathogens, synthetic vaccines are created using synthetic components, such as synthesized viral proteins, DNA, or RNA. These components mimic the disease-causing agent and trigger an immune response without causing the actual disease. The use of synthetic vaccines offers advantages in terms of safety, consistency, and scalability in production, making them valuable tools for preventing infectious diseases.

Bacterial vaccines are types of vaccines that are created using bacteria or parts of bacteria as the immunogen, which is the substance that triggers an immune response in the body. The purpose of a bacterial vaccine is to stimulate the immune system to develop protection against specific bacterial infections.

There are several types of bacterial vaccines, including:

1. Inactivated or killed whole-cell vaccines: These vaccines contain entire bacteria that have been killed or inactivated through various methods, such as heat or chemicals. The bacteria can no longer cause disease, but they still retain the ability to stimulate an immune response.
2. Subunit, protein, or polysaccharide vaccines: These vaccines use specific components of the bacterium, such as proteins or polysaccharides, that are known to trigger an immune response. By using only these components, the vaccine can avoid using the entire bacterium, which may reduce the risk of adverse reactions.
3. Live attenuated vaccines: These vaccines contain live bacteria that have been weakened or attenuated so that they cannot cause disease but still retain the ability to stimulate an immune response. This type of vaccine can provide long-lasting immunity, but it may not be suitable for people with weakened immune systems.

Bacterial vaccines are essential tools in preventing and controlling bacterial infections, reducing the burden of diseases such as tuberculosis, pneumococcal disease, meningococcal disease, and Haemophilus influenzae type b (Hib) disease. They work by exposing the immune system to a harmless form of the bacteria or its components, which triggers the production of antibodies and memory cells that can recognize and fight off future infections with that same bacterium.

It's important to note that while vaccines are generally safe and effective, they may cause mild side effects such as pain, redness, or swelling at the injection site, fever, or fatigue. Serious side effects are rare but can occur, so it's essential to consult with a healthcare provider before receiving any vaccine.

An AIDS vaccine is a type of preventive vaccine that aims to stimulate the immune system to produce an effective response against the human immunodeficiency virus (HIV), which causes acquired immunodeficiency syndrome (AIDS). The goal of an AIDS vaccine is to induce the production of immune cells and proteins that can recognize and eliminate HIV-infected cells, thereby preventing the establishment of a persistent infection.

Despite decades of research, there is still no licensed AIDS vaccine available. This is due in part to the unique challenges posed by HIV, which has a high mutation rate and can rapidly evolve to evade the immune system's defenses. However, several promising vaccine candidates are currently being tested in clinical trials around the world, and researchers continue to explore new approaches and strategies for developing an effective AIDS vaccine.

A subunit vaccine is a type of vaccine that contains a specific piece or component of the microorganism (such as a protein, sugar, or part of the bacterial outer membrane), instead of containing the entire organism. This piece of the microorganism is known as an antigen, and it stimulates an immune response in the body, allowing the development of immunity against the targeted infection without introducing the risk of disease associated with live vaccines.

Subunit vaccines offer several advantages over other types of vaccines. They are generally safer because they do not contain live or weakened microorganisms, making them suitable for individuals with weakened immune systems or specific medical conditions that prevent them from receiving live vaccines. Additionally, subunit vaccines can be designed to focus on the most immunogenic components of a pathogen, potentially leading to stronger and more targeted immune responses.

Examples of subunit vaccines include the Hepatitis B vaccine, which contains a viral protein, and the Haemophilus influenzae type b (Hib) vaccine, which uses pieces of the bacterial polysaccharide capsule. These vaccines have been crucial in preventing serious infectious diseases and reducing associated complications worldwide.

Conjugate vaccines are a type of vaccine that combines a part of a bacterium with a protein or other substance to boost the body's immune response to the bacteria. The bacterial component is usually a polysaccharide, which is a long chain of sugars that makes up part of the bacterial cell wall.

By itself, a polysaccharide is not very immunogenic, meaning it does not stimulate a strong immune response. However, when it is conjugated or linked to a protein or other carrier molecule, it becomes much more immunogenic and can elicit a stronger and longer-lasting immune response.

Conjugate vaccines are particularly effective in protecting against bacterial infections that affect young children, such as Haemophilus influenzae type b (Hib) and pneumococcal disease. These vaccines have been instrumental in reducing the incidence of these diseases and their associated complications, such as meningitis and pneumonia.

Overall, conjugate vaccines work by mimicking a natural infection and stimulating the immune system to produce antibodies that can protect against future infections with the same bacterium. By combining a weakly immunogenic polysaccharide with a protein carrier, these vaccines can elicit a stronger and more effective immune response, providing long-lasting protection against bacterial infections.

Vaccination is a simple, safe, and effective way to protect people against harmful diseases, before they come into contact with them. It uses your body's natural defenses to build protection to specific infections and makes your immune system stronger.

A vaccination usually contains a small, harmless piece of a virus or bacteria (or toxins produced by these germs) that has been made inactive or weakened so it won't cause the disease itself. This piece of the germ is known as an antigen. When the vaccine is introduced into the body, the immune system recognizes the antigen as foreign and produces antibodies to fight it.

If a person then comes into contact with the actual disease-causing germ, their immune system will recognize it and immediately produce antibodies to destroy it. The person is therefore protected against that disease. This is known as active immunity.

Vaccinations are important for both individual and public health. They prevent the spread of contagious diseases and protect vulnerable members of the population, such as young children, the elderly, and people with weakened immune systems who cannot be vaccinated or for whom vaccination is not effective.

Malaria vaccines are biological preparations that induce immunity against malaria parasites, thereby preventing or reducing the severity of malaria disease. They typically contain antigens (proteins or other molecules derived from the parasite) that stimulate an immune response in the recipient, enabling their body to recognize and neutralize the pathogen upon exposure.

The most advanced malaria vaccine candidate is RTS,S/AS01 (Mosquirix), which targets the Plasmodium falciparum parasite's circumsporozoite protein (CSP). This vaccine has shown partial protection in clinical trials, reducing the risk of severe malaria and hospitalization in young children by about 30% over four years. However, it does not provide complete immunity, and additional research is ongoing to develop more effective vaccines against malaria.

Papillomavirus vaccines are vaccines that have been developed to prevent infection by human papillomaviruses (HPV). HPV is a DNA virus that is capable of infecting the skin and mucous membranes. Certain types of HPV are known to cause cervical cancer, as well as other types of cancer such as anal, penile, vulvar, and oropharyngeal cancers. Other types of HPV can cause genital warts.

There are currently two papillomavirus vaccines that have been approved for use in the United States: Gardasil and Cervarix. Both vaccines protect against the two most common cancer-causing types of HPV (types 16 and 18), which together cause about 70% of cervical cancers. Gardasil also protects against the two most common types of HPV that cause genital warts (types 6 and 11).

Papillomavirus vaccines are given as a series of three shots over a period of six months. They are most effective when given to people before they become sexually active, as this reduces the risk of exposure to HPV. The Centers for Disease Control and Prevention (CDC) recommends that all boys and girls get vaccinated against HPV at age 11 or 12, but the vaccine can be given to people as young as age 9 and as old as age 26.

It is important to note that papillomavirus vaccines do not protect against all types of HPV, and they do not treat existing HPV infections or cervical cancer. They are intended to prevent new HPV infections and the cancers and other diseases that can be caused by HPV.

Meningococcal vaccines are vaccines that protect against Neisseria meningitidis, a type of bacteria that can cause serious infections such as meningitis (inflammation of the lining of the brain and spinal cord) and septicemia (bloodstream infection). There are several types of meningococcal vaccines available, including conjugate vaccines and polysaccharide vaccines. These vaccines work by stimulating the immune system to produce antibodies that can protect against the different serogroups of N. meningitidis, including A, B, C, Y, and W-135. The specific type of vaccine used and the number of doses required may depend on a person's age, health status, and other factors. Meningococcal vaccines are recommended for certain high-risk populations, such as infants, young children, adolescents, and people with certain medical conditions, as well as for travelers to areas where meningococcal disease is common.

"Hepatitis B vaccines are vaccines that prevent infection caused by the hepatitis B virus. They work by introducing a small and harmless piece of the virus to your body, which triggers your immune system to produce antibodies to fight off the infection. These antibodies remain in your body and provide protection if you are exposed to the real hepatitis B virus in the future.

The hepatitis B vaccine is typically given as a series of three shots over a six-month period. It is recommended for all infants, children and adolescents who have not previously been vaccinated, as well as for adults who are at increased risk of infection, such as healthcare workers, people who inject drugs, and those with certain medical conditions.

It's important to note that hepatitis B vaccine does not provide protection against other types of viral hepatitis, such as hepatitis A or C."

A measles vaccine is a biological preparation that induces immunity against the measles virus. It contains an attenuated (weakened) strain of the measles virus, which stimulates the immune system to produce antibodies that protect against future infection with the wild-type (disease-causing) virus. Measles vaccines are typically administered in combination with vaccines against mumps and rubella (German measles), forming the MMR vaccine.

The measles vaccine is highly effective, with one or two doses providing immunity in over 95% of people who receive it. It is usually given to children as part of routine childhood immunization programs, with the first dose administered at 12-15 months of age and the second dose at 4-6 years of age.

Measles vaccination has led to a dramatic reduction in the incidence of measles worldwide and is considered one of the greatest public health achievements of the past century. However, despite widespread availability of the vaccine, measles remains a significant cause of morbidity and mortality in some parts of the world, particularly in areas with low vaccination coverage or where access to healthcare is limited.

A Pertussis vaccine is a type of immunization used to protect against pertussis, also known as whooping cough. It contains components that stimulate the immune system to produce antibodies against the bacteria that cause pertussis, Bordetella pertussis. There are two main types of pertussis vaccines: whole-cell pertussis (wP) vaccines and acellular pertussis (aP) vaccines. wP vaccines contain killed whole cells of B. pertussis, while aP vaccines contain specific components of the bacteria, such as pertussis toxin and other antigens. Pertussis vaccines are often combined with diphtheria and tetanus to form combination vaccines, such as DTaP (diphtheria, tetanus, and acellular pertussis) and TdaP (tetanus, diphtheria, and acellular pertussis). These vaccines are typically given to young children as part of their routine immunization schedule.

Haemophilus vaccines are vaccines that are designed to protect against Haemophilus influenzae type b (Hib), a bacterium that can cause serious infections such as meningitis, pneumonia, and epiglottitis. There are two main types of Hib vaccines:

1. Polysaccharide vaccine: This type of vaccine is made from the sugar coating (polysaccharide) of the bacterial cells. It is not effective in children under 2 years of age because their immune systems are not yet mature enough to respond effectively to this type of vaccine.
2. Conjugate vaccine: This type of vaccine combines the polysaccharide with a protein carrier, which helps to stimulate a stronger and more sustained immune response. It is effective in infants as young as 6 weeks old.

Hib vaccines are usually given as part of routine childhood immunizations starting at 2 months of age. They are administered through an injection into the muscle. The vaccine is safe and effective, with few side effects. Vaccination against Hib has led to a significant reduction in the incidence of Hib infections worldwide.

BCG (Bacillus Calmette-Guérin) vaccine is a type of immunization used primarily to prevent tuberculosis (TB). It contains a live but weakened strain of Mycobacterium bovis, which is related to the bacterium that causes TB in humans (Mycobacterium tuberculosis).

The BCG vaccine works by stimulating an immune response in the body, enabling it to better resist infection with TB bacteria if exposed in the future. It is often given to infants and children in countries where TB is common, and its use varies depending on the national immunization policies. The protection offered by the BCG vaccine is moderate and may not last for a very long time.

In addition to its use against TB, the BCG vaccine has also been investigated for its potential therapeutic role in treating bladder cancer and some other types of cancer. The mechanism of action in these cases is thought to be related to the vaccine's ability to stimulate an immune response against abnormal cells.

Poliovirus Vaccine, Inactivated (IPV) is a vaccine used to prevent poliomyelitis (polio), a highly infectious disease caused by the poliovirus. IPV contains inactivated (killed) polioviruses of all three poliovirus types. It works by stimulating an immune response in the body, but because the viruses are inactivated, they cannot cause polio. After vaccination, the immune system recognizes and responds to the inactivated viruses, producing antibodies that protect against future infection with wild, or naturally occurring, polioviruses. IPV is typically given as an injection in the leg or arm, and a series of doses are required for full protection. It is a safe and effective way to prevent polio and its complications.

Rabies vaccines are medical products that contain antigens of the rabies virus, which stimulate an immune response in individuals who receive them. The purpose of rabies vaccines is to prevent the development of rabies, a viral disease that is almost always fatal once symptoms appear.

There are two primary types of rabies vaccines available:

1. Pre-exposure prophylaxis (PrEP) vaccines: These vaccines are given to individuals who are at high risk of coming into contact with the rabies virus, such as veterinarians, animal handlers, and travelers visiting areas where rabies is common. The vaccine series typically consists of three doses given over a period of 28 days.
2. Post-exposure prophylaxis (PEP) vaccines: These vaccines are administered to individuals who have already been exposed to the rabies virus, usually through a bite or scratch from an infected animal. The vaccine series typically consists of four doses given over a period of 14 days, along with a dose of rabies immune globulin (RIG) to provide immediate protection while the immune system responds to the vaccine.

Both types of rabies vaccines are highly effective at preventing the disease, but it is essential to receive them as soon as possible after exposure or before potential exposure, as the virus can be fatal if left untreated.

Rotavirus vaccines are preventive measures used to protect against rotavirus infections, which are the leading cause of severe diarrhea and dehydration among infants and young children worldwide. These vaccines contain weakened or inactivated forms of the rotavirus, a pathogen that infects and causes symptoms by multiplying inside cells lining the small intestine.

The weakened or inactivated virus in the vaccine stimulates an immune response in the body, enabling it to recognize and fight off future rotavirus infections more effectively. The vaccines are usually administered orally, as a liquid droplet or on a sugar cube, to mimic natural infection through the gastrointestinal tract.

There are currently two licensed rotavirus vaccines available globally:

1. Rotarix (GlaxoSmithKline): This vaccine contains an attenuated (weakened) strain of human rotavirus and is given in a two-dose series, typically at 2 and 4 months of age.
2. RotaTeq (Merck): This vaccine contains five reassortant viruses, combining human and animal strains to provide broader protection. It is administered in a three-dose series, usually at 2, 4, and 6 months of age.

Rotavirus vaccines have been shown to significantly reduce the incidence of severe rotavirus gastroenteritis and related hospitalizations among infants and young children. The World Health Organization (WHO) recommends the inclusion of rotavirus vaccination in national immunization programs, particularly in countries with high child mortality rates due to diarrheal diseases.

Cholera vaccines are preventive measures used to protect against the infection caused by the bacterium Vibrio cholerae. There are several types of cholera vaccines available, including:

1. Inactivated oral vaccine (ICCV): This vaccine contains killed whole-cell bacteria and is given in two doses, with each dose administered at least 14 days apart. It provides protection for up to six months and can be given to adults and children over the age of one year.
2. Live attenuated oral vaccine (LCV): This vaccine contains weakened live bacteria that are unable to cause disease but still stimulate an immune response. The most commonly used LCV is called CVD 103-HgR, which is given in a single dose and provides protection for up to three months. It can be given to adults and children over the age of six years.
3. Injectable cholera vaccine: This vaccine contains inactivated bacteria and is given as an injection. It is not widely available and its effectiveness is limited compared to oral vaccines.

Cholera vaccines are recommended for travelers visiting areas with known cholera outbreaks, particularly if they plan to eat food or drink water that may be contaminated. They can also be used in response to outbreaks to help control the spread of the disease. However, it is important to note that vaccination alone is not sufficient to prevent cholera infection and good hygiene practices, such as handwashing and safe food handling, should always be followed.

Typhoid-Paratyphoid vaccines are immunizations that protect against typhoid fever and paratyphoid fevers, which are caused by the Salmonella enterica serovars Typhi and Paratyphi, respectively. These vaccines contain inactivated or attenuated bacteria or specific antigens that stimulate an individual's immune system to develop immunity against these diseases without causing the illness itself. There are several types of typhoid-paratyphoid vaccines available, including:

1. Ty21a (oral live attenuated vaccine): This is a live but weakened form of the Salmonella Typhi bacteria. It is given orally in capsule form and requires a series of 4 doses taken every other day. The vaccine provides protection for about 5-7 years.
2. Vi polysaccharide (ViPS) typhoid vaccine: This vaccine contains purified Vi antigens from the Salmonella Typhi bacterium's outer capsular layer. It is given as an injection and provides protection for approximately 2-3 years.
3. Combined typhoid-paratyphoid A and B vaccines (Vi-rEPA): This vaccine combines Vi polysaccharide antigens from Salmonella Typhi and Paratyphi A and B. It is given as an injection and provides protection for about 3 years against typhoid fever and paratyphoid fevers A and B.
4. Typhoid conjugate vaccines (TCVs): These vaccines combine the Vi polysaccharide antigen from Salmonella Typhi with a protein carrier to enhance the immune response, particularly in children under 2 years of age. TCVs are given as an injection and provide long-lasting protection against typhoid fever.

It is important to note that none of these vaccines provides 100% protection, but they significantly reduce the risk of contracting typhoid or paratyphoid fevers. Additionally, good hygiene practices, such as handwashing and safe food handling, can further minimize the risk of infection.

The Smallpox vaccine is not a live virus vaccine but is instead made from a vaccinia virus, which is a virus related to the variola virus (the virus that causes smallpox). The vaccinia virus used in the vaccine does not cause smallpox, but it does cause a milder illness with symptoms such as a fever and a rash of pustules or blisters at the site of inoculation.

The smallpox vaccine was first developed by Edward Jenner in 1796 and is one of the oldest vaccines still in use today. It has been highly effective in preventing smallpox, which was once a major cause of death and disability worldwide. In fact, smallpox was declared eradicated by the World Health Organization (WHO) in 1980, thanks in large part to the widespread use of the smallpox vaccine.

Despite the eradication of smallpox, the smallpox vaccine is still used today in certain circumstances. For example, it may be given to laboratory workers who handle the virus or to military personnel who may be at risk of exposure to the virus. The vaccine may also be used as an emergency measure in the event of a bioterrorism attack involving smallpox.

It is important to note that the smallpox vaccine is not without risks and can cause serious side effects, including a severe allergic reaction (anaphylaxis), encephalitis (inflammation of the brain), and myocarditis (inflammation of the heart muscle). As a result, it is only given to people who are at high risk of exposure to the virus and who have been determined to be good candidates for vaccination by a healthcare professional.

A tuberculosis vaccine, also known as the BCG (Bacillus Calmette-Guérin) vaccine, is a type of immunization used to prevent tuberculosis (TB), a bacterial infection caused by Mycobacterium tuberculosis. The BCG vaccine contains a weakened strain of the bacteria that causes TB in cattle.

The BCG vaccine works by stimulating an immune response in the body, which helps to protect against severe forms of TB, such as TB meningitis and TB in children. However, it is not very effective at preventing pulmonary TB (TB that affects the lungs) in adults.

The BCG vaccine is not routinely recommended for use in the United States due to the low risk of TB infection in the general population. However, it may be given to people who are at high risk of exposure to TB, such as healthcare workers, laboratory personnel, and people traveling to countries with high rates of TB.

It is important to note that the BCG vaccine does not provide complete protection against TB and that other measures, such as testing and treatment for latent TB infection, are also important for controlling the spread of this disease.

Antibodies, viral are proteins produced by the immune system in response to an infection with a virus. These antibodies are capable of recognizing and binding to specific antigens on the surface of the virus, which helps to neutralize or destroy the virus and prevent its replication. Once produced, these antibodies can provide immunity against future infections with the same virus.

Viral antibodies are typically composed of four polypeptide chains - two heavy chains and two light chains - that are held together by disulfide bonds. The binding site for the antigen is located at the tip of the Y-shaped structure, formed by the variable regions of the heavy and light chains.

There are five classes of antibodies in humans: IgA, IgD, IgE, IgG, and IgM. Each class has a different function and is distributed differently throughout the body. For example, IgG is the most common type of antibody found in the bloodstream and provides long-term immunity against viruses, while IgA is found primarily in mucous membranes and helps to protect against respiratory and gastrointestinal infections.

In addition to their role in the immune response, viral antibodies can also be used as diagnostic tools to detect the presence of a specific virus in a patient's blood or other bodily fluids.

The chickenpox vaccine, also known as varicella vaccine, is a preventive measure against the highly contagious viral infection caused by the varicella-zoster virus. The vaccine contains a live but weakened form of the virus, which stimulates the immune system to produce a response without causing the disease itself.

The chickenpox vaccine is typically given in two doses, with the first dose administered between 12 and 15 months of age and the second dose between 4 and 6 years of age. In some cases, the vaccine may be given to older children, adolescents, or adults who have not previously been vaccinated or who have never had chickenpox.

The chickenpox vaccine is highly effective at preventing severe cases of the disease and reducing the risk of complications such as bacterial infections, pneumonia, and encephalitis. It is also effective at preventing transmission of the virus to others.

Like any vaccine, the chickenpox vaccine can cause mild side effects such as soreness at the injection site, fever, or a mild rash. However, these side effects are generally mild and short-lived. Serious side effects are rare but may include allergic reactions or severe immune responses.

Overall, the chickenpox vaccine is a safe and effective way to prevent this common childhood disease and its potential complications.

The Diphtheria-Tetanus-Pertussis (DTaP) vaccine is a combination immunization that protects against three bacterial diseases: diphtheria, tetanus (lockjaw), and pertussis (whooping cough).

Diphtheria is an upper respiratory infection that can lead to breathing difficulties, heart failure, paralysis, or even death. Tetanus is a bacterial infection that affects the nervous system and causes muscle stiffness and spasms, leading to "lockjaw." Pertussis is a highly contagious respiratory infection characterized by severe coughing fits, which can make it difficult to breathe and may lead to pneumonia, seizures, or brain damage.

The DTaP vaccine contains inactivated toxins (toxoids) from the bacteria that cause these diseases. It is typically given as a series of five shots, with doses administered at 2 months, 4 months, 6 months, 15-18 months, and 4-6 years of age. The vaccine helps the immune system develop protection against the diseases without causing the actual illness.

It is important to note that there are other combination vaccines available that protect against these same diseases, such as DT (diphtheria and tetanus toxoids) and Tdap (tetanus, diphtheria, and acellular pertussis), which contain higher doses of the diphtheria and pertussis components. These vaccines are recommended for different age groups and may be used as booster shots to maintain immunity throughout adulthood.

The Mumps Vaccine is a biological preparation intended to induce immunity against mumps, a contagious viral infection that primarily affects the salivary glands. The vaccine contains live attenuated (weakened) mumps virus, which stimulates the immune system to develop a protective response without causing the disease.

There are two types of mumps vaccines available:

1. The Jeryl Lynn strain is used in the United States and is part of the Measles, Mumps, and Rubella (MMR) vaccine and the Measles, Mumps, Rubella, and Varicella (MMRV) vaccine. This strain is derived from a clinical isolate obtained from the throat washings of a child with mumps in 1963.
2. The Urabe AM9 strain was used in some countries but has been discontinued in many places due to an increased risk of meningitis as a rare complication.

The MMR vaccine is typically given to children at 12-15 months of age and again at 4-6 years of age, providing long-lasting immunity against mumps in most individuals. The vaccine has significantly reduced the incidence of mumps and its complications worldwide.

Hepatitis A vaccines are inactivated or live attenuated viral vaccines that are administered to prevent infection and illness caused by the hepatitis A virus. The vaccine contains antigens that stimulate an immune response in the body, leading to the production of antibodies that protect against future infection with the virus.

The inactivated hepatitis A vaccine is made from viruses that have been chemically treated to destroy their ability to cause disease while preserving their ability to stimulate an immune response. This type of vaccine is typically given in two doses, six months apart, and provides long-term protection against the virus.

The live attenuated hepatitis A vaccine contains a weakened form of the virus that is unable to cause illness but can still stimulate an immune response. This type of vaccine is given as a single dose and provides protection against the virus for at least 20 years.

Hepatitis A vaccines are recommended for people who are at increased risk of infection, including travelers to areas where hepatitis A is common, men who have sex with men, people who use injection drugs, and people with chronic liver disease or clotting factor disorders. The vaccine is also recommended for children in certain states and communities where hepatitis A is endemic.

An immunization schedule is a series of planned dates when a person, usually a child, should receive specific vaccines in order to be fully protected against certain preventable diseases. The schedule is developed based on scientific research and recommendations from health organizations such as the World Health Organization (WHO) and the Centers for Disease Control and Prevention (CDC).

The immunization schedule outlines which vaccines are recommended, the number of doses required, the age at which each dose should be given, and the minimum amount of time that must pass between doses. The schedule may vary depending on factors such as the individual's age, health status, and travel plans.

Immunization schedules are important for ensuring that individuals receive timely protection against vaccine-preventable diseases, and for maintaining high levels of immunity in populations, which helps to prevent the spread of disease. It is important to follow the recommended immunization schedule as closely as possible to ensure optimal protection.

Immunologic adjuvants are substances that are added to a vaccine to enhance the body's immune response to the antigens contained in the vaccine. They work by stimulating the immune system and promoting the production of antibodies and activating immune cells, such as T-cells and macrophages, which help to provide a stronger and more sustained immune response to the vaccine.

Immunologic adjuvants can be derived from various sources, including bacteria, viruses, and chemicals. Some common examples include aluminum salts (alum), oil-in-water emulsions (such as MF59), and bacterial components (such as lipopolysaccharide or LPS).

The use of immunologic adjuvants in vaccines can help to improve the efficacy of the vaccine, particularly for vaccines that contain weak or poorly immunogenic antigens. They can also help to reduce the amount of antigen needed in a vaccine, which can be beneficial for vaccines that are difficult or expensive to produce.

It's important to note that while adjuvants can enhance the immune response to a vaccine, they can also increase the risk of adverse reactions, such as inflammation and pain at the injection site. Therefore, the use of immunologic adjuvants must be carefully balanced against their potential benefits and risks.

Secondary immunization, also known as "anamnestic response" or "booster," refers to the enhanced immune response that occurs upon re-exposure to an antigen, having previously been immunized or infected with the same pathogen. This response is characterized by a more rapid and robust production of antibodies and memory cells compared to the primary immune response. The secondary immunization aims to maintain long-term immunity against infectious diseases and improve vaccine effectiveness. It usually involves administering additional doses of a vaccine or booster shots after the initial series of immunizations, which helps reinforce the immune system's ability to recognize and combat specific pathogens.

The Measles-Mumps-Rubella (MMR) vaccine is a combination immunization that protects against three infectious diseases: measles, mumps, and rubella. It contains live attenuated viruses of each disease, which stimulate an immune response in the body similar to that produced by natural infection but do not cause the diseases themselves.

The MMR vaccine is typically given in two doses, the first at 12-15 months of age and the second at 4-6 years of age. It is highly effective in preventing these diseases, with over 90% effectiveness reported after a single dose and near 100% effectiveness after the second dose.

Measles is a highly contagious viral disease that can cause fever, rash, cough, runny nose, and red, watery eyes. It can also lead to serious complications such as pneumonia, encephalitis (inflammation of the brain), and even death.

Mumps is a viral infection that primarily affects the salivary glands, causing swelling and tenderness in the cheeks and jaw. It can also cause fever, headache, muscle aches, and fatigue. Mumps can lead to serious complications such as deafness, meningitis (inflammation of the membranes surrounding the brain and spinal cord), and inflammation of the testicles or ovaries.

Rubella, also known as German measles, is a viral infection that typically causes a mild fever, rash, and swollen lymph nodes. However, if a pregnant woman becomes infected with rubella, it can cause serious birth defects such as hearing impairment, heart defects, and developmental delays in the fetus.

The MMR vaccine is an important tool in preventing these diseases and protecting public health.

Streptococcal vaccines are immunizations designed to protect against infections caused by Streptococcus bacteria. These vaccines contain antigens, which are substances that trigger an immune response and help the body recognize and fight off specific types of Streptococcus bacteria. There are several different types of streptococcal vaccines available or in development, including:

1. Pneumococcal conjugate vaccine (PCV): This vaccine protects against Streptococcus pneumoniae, a type of bacteria that can cause pneumonia, meningitis, and other serious infections. PCV is recommended for all children under 2 years old, as well as older children and adults with certain medical conditions.
2. Pneumococcal polysaccharide vaccine (PPSV): This vaccine also protects against Streptococcus pneumoniae, but it is recommended for adults 65 and older, as well as younger people with certain medical conditions.
3. Streptococcus pyogenes vaccine: This vaccine is being developed to protect against Group A Streptococcus (GAS), which can cause a variety of infections, including strep throat, skin infections, and serious diseases like rheumatic fever and toxic shock syndrome. There are several different GAS vaccine candidates in various stages of development.
4. Streptococcus agalactiae vaccine: This vaccine is being developed to protect against Group B Streptococcus (GBS), which can cause serious infections in newborns, pregnant women, and older adults with certain medical conditions. There are several different GBS vaccine candidates in various stages of development.

Overall, streptococcal vaccines play an important role in preventing bacterial infections and reducing the burden of disease caused by Streptococcus bacteria.

Anthrax vaccines are biological preparations designed to protect against anthrax, a potentially fatal infectious disease caused by the bacterium Bacillus anthracis. Anthrax can affect both humans and animals, and it is primarily transmitted through contact with contaminated animal products or, less commonly, through inhalation of spores.

There are two types of anthrax vaccines currently available:

1. Anthrax Vaccine Adsorbed (AVA): This vaccine is licensed for use in the United States and is approved for pre-exposure prophylaxis in high-risk individuals, such as military personnel and laboratory workers who handle the bacterium. AVA contains a cell-free filtrate of cultured B. anthracis cells that have been chemically treated to render them non-infectious. The vaccine works by stimulating the production of antibodies against protective antigens (PA) present in the bacterial culture.
2. Recombinant Anthrax Vaccine (rPA): This vaccine, also known as BioThrax, is a newer generation anthrax vaccine that was approved for use in the United States in 2015. It contains only the recombinant protective antigen (rPA) of B. anthracis, which is produced using genetic engineering techniques. The rPA vaccine has been shown to be as effective as AVA in generating an immune response and offers several advantages, including a more straightforward manufacturing process, fewer side effects, and a longer shelf life.

Both vaccines require multiple doses for initial immunization, followed by periodic booster shots to maintain protection. Anthrax vaccines are generally safe and effective at preventing anthrax infection; however, they may cause mild to moderate side effects, such as soreness at the injection site, fatigue, and muscle aches. Severe allergic reactions are rare but possible.

It is important to note that anthrax vaccines do not provide immediate protection against anthrax infection. They require several weeks to stimulate an immune response, so they should be administered before potential exposure to the bacterium. In cases of known or suspected exposure to anthrax, antibiotics are used as a primary means of preventing and treating the disease.

Dengue vaccines are designed to protect against dengue fever, a mosquito-borne viral disease that can cause severe flu-like symptoms and potentially life-threatening complications. Dengue is caused by four distinct serotypes of the virus (DENV-1, DENV-2, DENV-3, and DENV-4), and infection with one serotype does not provide immunity against the others.

The first licensed dengue vaccine, Dengvaxia (CYD-TDV), is a chimeric yellow fever-dengue tetravalent vaccine developed by Sanofi Pasteur. It is approved for use in several countries and has demonstrated efficacy against dengue fever caused by all four serotypes in clinical trials. However, the vaccine has raised concerns about the risk of severe disease in individuals who have not been previously exposed to dengue. As a result, it is recommended primarily for people with a documented past dengue infection or living in areas with high dengue prevalence and where the benefits outweigh the risks.

Another dengue vaccine candidate, Takeda's TAK-003 (also known as TDV), is a live attenuated tetravalent dengue vaccine that has shown efficacy against all four serotypes in clinical trials. It was granted approval by the European Medicines Agency (EMA) and several other countries for use in individuals aged 4-16 years old, living in endemic areas.

Research and development of additional dengue vaccine candidates are ongoing to address concerns about safety, efficacy, and accessibility, particularly for at-risk populations in low- and middle-income countries where dengue is most prevalent.

Immunization is defined medically as the process where an individual is made immune or resistant to an infectious disease, typically through the administration of a vaccine. The vaccine stimulates the body's own immune system to recognize and fight off the specific disease-causing organism, thereby preventing or reducing the severity of future infections with that organism.

Immunization can be achieved actively, where the person is given a vaccine to trigger an immune response, or passively, where antibodies are transferred to the person through immunoglobulin therapy. Immunizations are an important part of preventive healthcare and have been successful in controlling and eliminating many infectious diseases worldwide.

Viral hepatitis vaccines are vaccines that prevent infection caused by various hepatitis viruses, including hepatitis A and B. These vaccines contain antigens that stimulate the immune system to produce antibodies that protect against infection with the corresponding virus. The vaccines are typically administered through injection and may require multiple doses for full protection.

The hepatitis A vaccine is made from inactivated hepatitis A virus, while the hepatitis B vaccine is made from recombinant hepatitis B surface antigen. Both vaccines have been shown to be highly effective in preventing infection and reducing the risk of complications associated with viral hepatitis, such as liver disease and liver cancer.

It's important to note that there are no vaccines available for other types of viral hepatitis, such as hepatitis C, D, or E. Prevention strategies for these types of viral hepatitis typically involve measures to reduce exposure to the virus, such as safe injection practices and avoiding high-risk behaviors like sharing needles or having unprotected sex with infected individuals.

Poliovirus Vaccine, Oral (OPV) is a vaccine used to prevent poliomyelitis (polio). It contains live attenuated (weakened) polioviruses, which stimulate an immune response in the body and provide protection against all three types of wild, infectious polioviruses. OPV is given by mouth, usually in drops, and it replicates in the gastrointestinal tract, where it induces a strong immune response. This response not only protects the individual who receives the vaccine but also helps to stop the spread of poliovirus in the community, providing indirect protection (herd immunity) to those who are not vaccinated. OPV is safe, effective, and easy to administer, making it an important tool for global polio eradication efforts. However, due to the risk of vaccine-associated paralytic polio (VAPP), inactivated poliovirus vaccine (IPV) is recommended for routine immunization in some countries.

The Yellow Fever Vaccine is a vaccine that protects against the yellow fever virus, which is transmitted to humans through the bites of infected mosquitoes. The vaccine contains live, weakened yellow fever virus, and it works by stimulating the immune system to produce an immune response that provides protection against the disease.

The yellow fever vaccine is recommended for people who are traveling to areas where yellow fever is common, including parts of Africa and South America. It is also required for entry into some countries in these regions. The vaccine is generally safe and effective, but it can cause mild side effects such as headache, muscle pain, and fever in some people. Serious side effects are rare, but may include allergic reactions or infection with the weakened virus used in the vaccine.

It's important to note that yellow fever vaccine may not be recommended for certain individuals, including infants younger than 6 months, pregnant women, people with weakened immune systems, and those with a history of severe allergic reaction to a previous dose of the vaccine or any component of the vaccine. It is always best to consult with a healthcare provider before receiving any vaccination.

Bacterial antibodies are a type of antibodies produced by the immune system in response to an infection caused by bacteria. These antibodies are proteins that recognize and bind to specific antigens on the surface of the bacterial cells, marking them for destruction by other immune cells. Bacterial antibodies can be classified into several types based on their structure and function, including IgG, IgM, IgA, and IgE. They play a crucial role in the body's defense against bacterial infections and provide immunity to future infections with the same bacteria.

A plague vaccine is a type of immunization used to protect against the bacterial infection caused by Yersinia pestis, the causative agent of plague. The vaccine contains killed or weakened forms of the bacteria, which stimulate the immune system to produce antibodies and activate immune cells that can recognize and fight off the infection if the person is exposed to the bacteria in the future.

There are several types of plague vaccines available, including whole-cell killed vaccines, live attenuated vaccines, and subunit vaccines. The choice of vaccine depends on various factors, such as the target population, the route of exposure (e.g., respiratory or cutaneous), and the desired duration of immunity.

Plague vaccines have been used for many years to protect military personnel and individuals at high risk of exposure to plague, such as laboratory workers and people living in areas where plague is endemic. However, their use is not widespread, and they are not currently recommended for general use in the United States or other developed countries.

It's important to note that while plague vaccines can provide some protection against the disease, they are not 100% effective, and other measures such as antibiotics and insect control are also important for preventing and treating plague infections.

A fungal vaccine is a biological preparation that provides active acquired immunity against fungal infections. It contains one or more fungal antigens, which are substances that can stimulate an immune response, along with adjuvants to enhance the immune response. The goal of fungal vaccines is to protect against invasive fungal diseases, especially in individuals with weakened immune systems, such as those undergoing chemotherapy, organ transplantation, or HIV/AIDS treatment.

Fungal vaccines can work by inducing both humoral and cell-mediated immunity. Humoral immunity involves the production of antibodies that recognize and neutralize fungal antigens, while cell-mediated immunity involves the activation of T cells to directly attack infected cells.

Currently, there are no licensed fungal vaccines available for human use, although several candidates are in various stages of development and clinical trials. Some examples include vaccines against Candida albicans, Aspergillus fumigatus, Cryptococcus neoformans, and Pneumocystis jirovecii.

Rubella vaccine is a preventive measure used to immunize individuals against rubella, also known as German measles. It contains inactivated or weakened forms of the rubella virus that stimulate an immune response when introduced into the body. The two types of rubella vaccines available are:

1. Live Attenuated Rubella Vaccine (RAV): This vaccine contains a weakened form of the rubella virus, which triggers an immune response without causing the disease. It is the most commonly used rubella vaccine and is often combined with measles and mumps vaccines to create the Measles-Mumps-Rubella (MMR) or Measles-Mumps-Rubella-Varicella (MMRV) vaccines.

2. Inactivated Rubella Vaccine: This vaccine contains a killed rubella virus, which is less commonly used but can still provide immunity against the disease.

The Centers for Disease Control and Prevention (CDC) recommends that children receive one dose of MMR vaccine at 12-15 months of age and another dose at 4-6 years of age. This schedule ensures optimal protection against rubella and other diseases included in the vaccines.

It is important to note that pregnant women should not receive the rubella vaccine, as it can potentially harm the developing fetus. Women who are planning to become pregnant should ensure they have had their rubella immunization before conceiving.

Acellular vaccines are a type of vaccine that contain one or more antigens but do not contain whole cell parts or components of the pathogen. They are designed to produce an immune response in the body that is specific to the antigen(s) contained within the vaccine, while minimizing the risk of adverse reactions associated with whole cell vaccines.

Acellular vaccines are often produced using recombinant DNA technology, where a specific gene from the pathogen is inserted into a different organism (such as yeast or bacteria) that can produce large quantities of the antigen. The antigen is then purified and used to create the vaccine.

One example of an acellular vaccine is the DTaP vaccine, which is used to protect against diphtheria, tetanus, and pertussis (whooping cough). This vaccine contains only a small portion of the pertussis bacterium, along with purified versions of the toxins produced by the bacteria. By contrast, whole cell pertussis vaccines contain entire killed bacteria, which can cause more frequent and severe side effects.

Overall, acellular vaccines offer a safer and more targeted approach to immunization than whole cell vaccines, while still providing effective protection against infectious diseases.

I believe there may be a slight confusion in your question. AIDS is a condition caused by the human immunodeficiency virus (HIV) infection, and it weakens the immune system, making people more susceptible to other infections and diseases. There is no vaccine for AIDS itself. However, there are vaccines being developed and tested to prevent HIV infection, which would help prevent AIDS from developing.

SAIDS is not a medical term. If you meant to ask about "HIV vaccines," I can provide a definition:

An HIV vaccine aims to stimulate the immune system to produce an effective response against the human immunodeficiency virus (HIV). An effective HIV vaccine would ideally prevent the initial infection or significantly reduce viral replication and disease progression in infected individuals. Currently, no licensed HIV vaccines are available, but research is ongoing to develop a protective vaccine against HIV infection.

Salmonella vaccines are immunizations that are developed to protect against Salmonella infections, which are caused by bacteria of the Salmonella enterica species. These vaccines typically contain antigens or weakened forms of the Salmonella bacteria that stimulate an immune response in the body, enabling it to recognize and fight off future Salmonella infections.

There are two main types of Salmonella vaccines:

1. Live Attenuated Vaccines: These vaccines contain weakened (attenuated) forms of the Salmonella bacteria that can still replicate but at a much slower rate and with reduced virulence compared to the wild-type bacteria. Examples include Ty21a, a live oral typhoid vaccine, and χ 144, an experimental live oral vaccine against nontyphoidal Salmonella serovars.
2. Inactivated (Killed) Vaccines: These vaccines contain killed Salmonella bacteria or their components, such as proteins or polysaccharides. They cannot replicate and are generally considered safer than live attenuated vaccines. However, they may not stimulate as strong an immune response compared to live vaccines. An example is the Vi polysaccharide vaccine against typhoid fever.

Salmonella vaccines are primarily used for preventing Salmonella infections in humans and animals, particularly those that cause typhoid fever and nontyphoidal Salmonella (NTS) infections. Vaccination is an essential component of controlling Salmonella infections, especially in areas with poor sanitation and hygiene, where the risk of exposure to Salmonella bacteria is higher.

Virus-like particles (VLPs) are nanostructures that mimic the organization and conformation of authentic viruses but lack the genetic material required for replication. VLPs can be produced from one or more viral proteins, which can be derived from various expression systems including bacteria, yeast, insect, or mammalian cells.

VLP-based vaccines are a type of vaccine that uses these virus-like particles to induce an immune response in the body. These vaccines can be designed to target specific viruses or other pathogens and have been shown to be safe and effective in inducing both humoral and cellular immunity.

VLPs resemble authentic viruses in their structure, size, and antigenic properties, making them highly immunogenic. They can be designed to present specific epitopes or antigens from a pathogen, which can stimulate the immune system to produce antibodies and activate T-cells that recognize and attack the pathogen.

VLP vaccines have been developed for several viruses, including human papillomavirus (HPV), hepatitis B virus (HBV), and respiratory syncytial virus (RSV). They offer several advantages over traditional vaccines, such as a strong immune response, safety, and stability.

BALB/c is an inbred strain of laboratory mouse that is widely used in biomedical research. The strain was developed at the Institute of Cancer Research in London by Henry Baldwin and his colleagues in the 1920s, and it has since become one of the most commonly used inbred strains in the world.

BALB/c mice are characterized by their black coat color, which is determined by a recessive allele at the tyrosinase locus. They are also known for their docile and friendly temperament, making them easy to handle and work with in the laboratory.

One of the key features of BALB/c mice that makes them useful for research is their susceptibility to certain types of tumors and immune responses. For example, they are highly susceptible to developing mammary tumors, which can be induced by chemical carcinogens or viral infection. They also have a strong Th2-biased immune response, which makes them useful models for studying allergic diseases and asthma.

BALB/c mice are also commonly used in studies of genetics, neuroscience, behavior, and infectious diseases. Because they are an inbred strain, they have a uniform genetic background, which makes it easier to control for genetic factors in experiments. Additionally, because they have been bred in the laboratory for many generations, they are highly standardized and reproducible, making them ideal subjects for scientific research.

Ebola vaccines are medical products designed to confer immunity against the Ebola virus, a deadly pathogen that causes hemorrhagic fever. Several Ebola vaccine candidates have been developed and tested in clinical trials, with some showing promising results. The most advanced Ebola vaccine is rVSV-ZEBOV, which has been shown to be highly effective in preventing the disease in clinical trials. It uses a weakened version of the vesicular stomatitis virus (VSV) to deliver a protein from the Ebola virus surface, triggering an immune response that protects against infection. Other Ebola vaccine candidates use different approaches, such as delivering Ebola virus genes using a harmless adenovirus vector or using inactivated whole Ebola viruses. These vaccines are still in development and have not yet been approved for widespread use.

Influenza, also known as the flu, is a highly contagious viral infection that attacks the respiratory system of humans. It is caused by influenza viruses A, B, or C and is characterized by the sudden onset of fever, chills, headache, muscle pain, sore throat, cough, runny nose, and fatigue. Influenza can lead to complications such as pneumonia, bronchitis, and ear infections, and can be particularly dangerous for young children, older adults, pregnant women, and people with weakened immune systems or chronic medical conditions. The virus is spread through respiratory droplets produced when an infected person coughs, sneezes, or talks, and can also survive on surfaces for a period of time. Influenza viruses are constantly changing, which makes it necessary to get vaccinated annually to protect against the most recent and prevalent strains.

Neutralizing antibodies are a type of antibody that defends against pathogens such as viruses or bacteria by neutralizing their ability to infect cells. They do this by binding to specific regions on the surface proteins of the pathogen, preventing it from attaching to and entering host cells. This renders the pathogen ineffective and helps to prevent or reduce the severity of infection. Neutralizing antibodies can be produced naturally in response to an infection or vaccination, or they can be generated artificially for therapeutic purposes.

Staphylococcal vaccines are immunizations that are developed to protect against infections caused by the Staphylococcus bacteria, particularly Staphylococcus aureus. These vaccines typically contain components of the bacterial cell wall or toxins that stimulate an immune response in the body, leading to the production of antibodies that can recognize and neutralize the bacteria if they invade the body in the future.

There are currently no licensed staphylococcal vaccines available for use in humans, although several candidates are in various stages of development. These vaccines aim to prevent a range of staphylococcal infections, including skin and soft tissue infections, pneumonia, bloodstream infections, and toxic shock syndrome.

It's important to note that while antibiotics can be effective against staphylococcal infections, the bacteria have become increasingly resistant to these drugs over time, making vaccines an important area of research and development for preventing and controlling the spread of these infections.

Diphtheria-Tetanus-acellular Pertussis (DTaP) vaccines are a type of combination vaccine that protect against three serious diseases caused by bacteria: diphtheria, tetanus, and pertussis (also known as whooping cough).

Diphtheria is a highly contagious respiratory infection that can cause breathing difficulties, heart failure, paralysis, and even death. Tetanus, also known as lockjaw, is a bacterial infection that affects the nervous system and causes muscle stiffness and spasms, which can be severe enough to cause broken bones or suffocation. Pertussis is a highly contagious respiratory infection that causes severe coughing fits, making it difficult to breathe, eat, or drink.

The "a" in DTaP stands for "acellular," which means that the pertussis component of the vaccine contains only parts of the bacteria, rather than the whole cells used in older vaccines. This reduces the risk of side effects associated with the whole-cell pertussis vaccine while still providing effective protection against the disease.

DTaP vaccines are typically given as a series of five shots, starting at 2 months of age and ending at 4-6 years of age. Booster doses may be recommended later in life to maintain immunity. DTaP vaccines are an essential part of routine childhood immunization schedules and have significantly reduced the incidence of these diseases worldwide.

Cytomegalovirus (CMV) vaccines are medical products being developed to prevent or ameliorate infection and disease caused by the human cytomegalovirus. CMV is a type of herpesvirus that can cause serious health problems in people with weakened immune systems, such as those undergoing organ transplantation, people living with HIV/AIDS, and newborns infected with the virus before birth (congenital CMV infection).

There are currently no approved vaccines for CMV. However, several vaccine candidates are being investigated in clinical trials to evaluate their safety, immunogenicity, and efficacy. These vaccine candidates use various approaches, such as:

1. Live-attenuated viruses: These vaccines contain weakened forms of the virus that can stimulate an immune response without causing disease. An example is the Towne vaccine, which has been studied in clinical trials for several decades.
2. Recombinant proteins: These vaccines use specific viral proteins to induce an immune response. For instance, a glycoprotein B (gB) subunit vaccine has shown promising results in phase II clinical trials.
3. Virus-like particles (VLPs): VLPs mimic the structure of the virus but do not contain any viral genetic material. They can be used to induce an immune response without causing infection.
4. DNA vaccines: These vaccines use plasmids containing CMV genes to stimulate an immune response. A DNA vaccine encoding the CMV phosphoprotein 65 (pp65) has been tested in clinical trials.
5. mRNA vaccines: Similar to DNA vaccines, mRNA vaccines use genetic material to induce an immune response. Moderna Therapeutics is developing an mRNA vaccine candidate for CMV.

The development of a safe and effective CMV vaccine remains a significant public health priority, as CMV infection can lead to severe complications in vulnerable populations.

Immunization programs, also known as vaccination programs, are organized efforts to administer vaccines to populations or communities in order to protect individuals from vaccine-preventable diseases. These programs are typically implemented by public health agencies and involve the planning, coordination, and delivery of immunizations to ensure that a high percentage of people are protected against specific infectious diseases.

Immunization programs may target specific age groups, such as infants and young children, or populations at higher risk of certain diseases, such as travelers, healthcare workers, or individuals with weakened immune systems. The goals of immunization programs include controlling and eliminating vaccine-preventable diseases, reducing the morbidity and mortality associated with these diseases, and protecting vulnerable populations from outbreaks and epidemics.

Immunization programs may be delivered through a variety of settings, including healthcare facilities, schools, community centers, and mobile clinics. They often involve partnerships between government agencies, healthcare providers, non-governmental organizations, and communities to ensure that vaccines are accessible, affordable, and acceptable to the populations they serve. Effective immunization programs require strong leadership, adequate funding, robust data systems, and ongoing monitoring and evaluation to assess their impact and identify areas for improvement.

"Intramuscular injections" refer to a medical procedure where a medication or vaccine is administered directly into the muscle tissue. This is typically done using a hypodermic needle and syringe, and the injection is usually given into one of the large muscles in the body, such as the deltoid (shoulder), vastus lateralis (thigh), or ventrogluteal (buttock) muscles.

Intramuscular injections are used for a variety of reasons, including to deliver medications that need to be absorbed slowly over time, to bypass stomach acid and improve absorption, or to ensure that the medication reaches the bloodstream quickly and directly. Common examples of medications delivered via intramuscular injection include certain vaccines, antibiotics, and pain relievers.

It is important to follow proper technique when administering intramuscular injections to minimize pain and reduce the risk of complications such as infection or injury to surrounding tissues. Proper site selection, needle length and gauge, and injection technique are all critical factors in ensuring a safe and effective intramuscular injection.

The Diphtheria-Tetanus vaccine, also known as the DT vaccine or Td vaccine (if diphtheria toxoid is not included), is a combination vaccine that protects against two potentially serious bacterial infections: diphtheria and tetanus.

Diphtheria is a respiratory infection that can cause breathing difficulties, heart problems, and nerve damage. Tetanus, also known as lockjaw, is a bacterial infection that affects the nervous system and causes muscle stiffness and spasms, particularly in the jaw and neck.

The vaccine contains small amounts of inactivated toxins (toxoids) from the bacteria that cause diphtheria and tetanus. When the vaccine is administered, it stimulates the immune system to produce antibodies that provide protection against these diseases.

In addition to protecting against diphtheria and tetanus, some formulations of the vaccine may also include protection against pertussis (whooping cough), polio, or hepatitis B. The DTaP vaccine is a similar combination vaccine that includes protection against diphtheria, tetanus, and pertussis, but uses acellular pertussis components instead of the whole-cell pertussis component used in the DT vaccine.

The Diphtheria-Tetanus vaccine is typically given as a series of shots in childhood, with booster shots recommended every 10 years to maintain immunity. It is an important part of routine childhood vaccination and is also recommended for adults who have not received the full series of shots or whose protection has waned over time.

Poliovirus vaccines are preparations used for active immunization against poliomyelitis, a highly infectious disease caused by the poliovirus. The two types of poliovirus vaccines available are:

1. Inactivated Poliovirus Vaccine (IPV): This vaccine contains inactivated (killed) poliovirus strains of all three serotypes. IPV is typically administered through an injection, usually in combination with other vaccines. It provides a strong immune response and does not carry the risk of vaccine-associated paralytic polio (VAPP), which is a rare but serious adverse event associated with the oral poliovirus vaccine (OPV).

2. Oral Poliovirus Vaccine (OPV): This vaccine contains live attenuated (weakened) poliovirus strains of all three serotypes. OPV is administered orally and induces both humoral and intestinal immunity, which helps prevent the spread of the virus in a community. However, there is a small risk of VAPP associated with this vaccine, especially after multiple doses. In rare cases, the weakened virus can revert to its virulent form and cause paralytic polio in the vaccinated individual or their close contacts.

Both IPV and OPV have been instrumental in global efforts to eradicate polio. The World Health Organization (WHO) recommends using IPV in routine immunization programs, while using OPV during supplementary immunization activities in areas with a high risk of poliovirus transmission.

Intranasal administration refers to the delivery of medication or other substances through the nasal passages and into the nasal cavity. This route of administration can be used for systemic absorption of drugs or for localized effects in the nasal area.

When a medication is administered intranasally, it is typically sprayed or dropped into the nostril, where it is absorbed by the mucous membranes lining the nasal cavity. The medication can then pass into the bloodstream and be distributed throughout the body for systemic effects. Intranasal administration can also result in direct absorption of the medication into the local tissues of the nasal cavity, which can be useful for treating conditions such as allergies, migraines, or pain in the nasal area.

Intranasal administration has several advantages over other routes of administration. It is non-invasive and does not require needles or injections, making it a more comfortable option for many people. Additionally, intranasal administration can result in faster onset of action than oral administration, as the medication bypasses the digestive system and is absorbed directly into the bloodstream. However, there are also some limitations to this route of administration, including potential issues with dosing accuracy and patient tolerance.

Escherichia coli (E. coli) vaccines are designed to protect against infections caused by various strains of the E. coli bacterium. These vaccines typically contain inactivated or attenuated (weakened) forms of the bacteria, which stimulate an immune response when introduced into the body. The immune system learns to recognize and fight off the specific strain of E. coli used in the vaccine, providing protection against future infections with that strain.

There are several types of E. coli vaccines available or in development, including:

1. Shiga toxin-producing E. coli (STEC) vaccines: These vaccines protect against STEC strains, such as O157:H7 and non-O157 STECs, which can cause severe illness, including hemorrhagic colitis and hemolytic uremic syndrome (HUS).
2. Enterotoxigenic E. coli (ETEC) vaccines: These vaccines target ETEC strains that are a common cause of traveler's diarrhea in people visiting areas with poor sanitation.
3. Enteropathogenic E. coli (EPEC) vaccines: EPEC strains can cause persistent diarrhea, especially in young children in developing countries. Vaccines against these strains are still in the research and development stage.
4. Extraintestinal pathogenic E. coli (ExPEC) vaccines: These vaccines aim to protect against ExPEC strains that can cause urinary tract infections, sepsis, and meningitis.

It is important to note that different E. coli vaccines are designed for specific purposes and may not provide cross-protection against other strains or types of E. coli infections.

Immunoglobulin G (IgG) is a type of antibody, which is a protective protein produced by the immune system in response to foreign substances like bacteria or viruses. IgG is the most abundant type of antibody in human blood, making up about 75-80% of all antibodies. It is found in all body fluids and plays a crucial role in fighting infections caused by bacteria, viruses, and toxins.

IgG has several important functions:

1. Neutralization: IgG can bind to the surface of bacteria or viruses, preventing them from attaching to and infecting human cells.
2. Opsonization: IgG coats the surface of pathogens, making them more recognizable and easier for immune cells like neutrophils and macrophages to phagocytose (engulf and destroy) them.
3. Complement activation: IgG can activate the complement system, a group of proteins that work together to help eliminate pathogens from the body. Activation of the complement system leads to the formation of the membrane attack complex, which creates holes in the cell membranes of bacteria, leading to their lysis (destruction).
4. Antibody-dependent cellular cytotoxicity (ADCC): IgG can bind to immune cells like natural killer (NK) cells and trigger them to release substances that cause target cells (such as virus-infected or cancerous cells) to undergo apoptosis (programmed cell death).
5. Immune complex formation: IgG can form immune complexes with antigens, which can then be removed from the body through various mechanisms, such as phagocytosis by immune cells or excretion in urine.

IgG is a critical component of adaptive immunity and provides long-lasting protection against reinfection with many pathogens. It has four subclasses (IgG1, IgG2, IgG3, and IgG4) that differ in their structure, function, and distribution in the body.

West Nile Virus (WNV) vaccines are immunizations that are designed to protect against the West Nile virus, which is a single-stranded RNA virus that belongs to the family Flaviviridae. The virus is primarily transmitted to humans through the bite of infected mosquitoes, particularly those of the Culex species.

There are currently no licensed WNV vaccines available for human use in the United States or Europe. However, there are several veterinary vaccines that have been developed and approved for use in horses and other animals, such as birds and geese. These vaccines work by stimulating the immune system to produce antibodies against the virus, which can help prevent infection and reduce the severity of symptoms in animals that do become infected.

Human WNV vaccine candidates are in various stages of development and testing. Some of these vaccines use inactivated or weakened forms of the virus, while others use only a portion of the viral protein to stimulate an immune response. While these vaccines have shown promise in clinical trials, further research is needed to determine their safety and effectiveness in larger populations before they can be approved for widespread use.

Hemagglutination inhibition (HI) tests are a type of serological assay used in medical laboratories to detect and measure the amount of antibodies present in a patient's serum. These tests are commonly used to diagnose viral infections, such as influenza or HIV, by identifying the presence of antibodies that bind to specific viral antigens and prevent hemagglutination (the agglutination or clumping together of red blood cells).

In an HI test, a small amount of the patient's serum is mixed with a known quantity of the viral antigen, which has been treated to attach to red blood cells. If the patient's serum contains antibodies that bind to the viral antigen, they will prevent the antigen from attaching to the red blood cells and inhibit hemagglutination. The degree of hemagglutination inhibition can be measured and used to estimate the amount of antibody present in the patient's serum.

HI tests are relatively simple and inexpensive to perform, but they have some limitations. For example, they may not detect early-stage infections before the body has had a chance to produce antibodies, and they may not be able to distinguish between different strains of the same virus. Nonetheless, HI tests remain an important tool for diagnosing viral infections and monitoring immune responses to vaccination or infection.

Shigella vaccines are immunizations that are developed to protect against Shigella infection, which is caused by the bacterium Shigella spp. These vaccines aim to stimulate the immune system to produce an immune response (the production of antibodies and activation of immune cells) that will provide protection against future Shigella infections.

There are currently no licensed Shigella vaccines available for use, although several candidate vaccines are in various stages of development and clinical trials. These vaccines typically contain inactivated or attenuated (weakened) forms of the bacteria, or specific components of the bacteria that can stimulate an immune response.

Shigella infection can cause a range of symptoms, including diarrhea, fever, abdominal cramps, and tenesmus (the strong, frequent urge to have a bowel movement). In severe cases, it can lead to complications such as dehydration, seizures, and hemolytic-uremic syndrome (HUS), which is a serious condition that can cause kidney failure. Shigella infection is most commonly transmitted through contaminated food or water, or direct contact with an infected person's feces.

Neutralization tests are a type of laboratory assay used in microbiology and immunology to measure the ability of a substance, such as an antibody or antitoxin, to neutralize the activity of a toxin or infectious agent. In these tests, the substance to be tested is mixed with a known quantity of the toxin or infectious agent, and the mixture is then incubated under controlled conditions. After incubation, the mixture is tested for residual toxicity or infectivity using a variety of methods, such as cell culture assays, animal models, or biochemical assays.

The neutralization titer is then calculated based on the highest dilution of the test substance that completely neutralizes the toxin or infectious agent. Neutralization tests are commonly used in the diagnosis and evaluation of immune responses to vaccines, as well as in the detection and quantification of toxins and other harmful substances.

Examples of neutralization tests include the serum neutralization test for measles antibodies, the plaque reduction neutralization test (PRNT) for dengue virus antibodies, and the cytotoxicity neutralization assay for botulinum neurotoxins.

Antibody formation, also known as humoral immune response, is the process by which the immune system produces proteins called antibodies in response to the presence of a foreign substance (antigen) in the body. This process involves several steps:

1. Recognition: The antigen is recognized and bound by a type of white blood cell called a B lymphocyte or B cell, which then becomes activated.
2. Differentiation: The activated B cell undergoes differentiation to become a plasma cell, which is a type of cell that produces and secretes large amounts of antibodies.
3. Antibody production: The plasma cells produce and release antibodies, which are proteins made up of four polypeptide chains (two heavy chains and two light chains) arranged in a Y-shape. Each antibody has two binding sites that can recognize and bind to specific regions on the antigen called epitopes.
4. Neutralization or elimination: The antibodies bind to the antigens, neutralizing them or marking them for destruction by other immune cells. This helps to prevent the spread of infection and protect the body from harmful substances.

Antibody formation is an important part of the adaptive immune response, which allows the body to specifically recognize and respond to a wide variety of pathogens and foreign substances.

The Herpes Zoster vaccine, also known as the shingles vaccine, is a preventive measure against the reactivation of the varicella-zoster virus (VZV) in individuals who have previously had chickenpox. The vaccine contains a live but weakened form of VZV that boosts the immune system's ability to recognize and fight off the virus, thereby reducing the risk of developing shingles and its complications. It is typically administered as a single dose for people aged 50 and older, or as a two-dose series for those aged 19 and older who have weakened immune systems.

Polysorbates are a type of nonionic surfactant (a compound that lowers the surface tension between two substances, such as oil and water) commonly used in pharmaceuticals, foods, and cosmetics. They are derived from sorbitol and reacted with ethylene oxide to create a polyoxyethylene structure. The most common types of polysorbates used in medicine are polysorbate 20, polysorbate 40, and polysorbate 60, which differ in the number of oxyethylene groups in their molecular structure.

Polysorbates are often added to pharmaceutical formulations as emulsifiers, solubilizers, or stabilizers. They help to improve the solubility and stability of drugs that are otherwise insoluble in water, allowing for better absorption and bioavailability. Polysorbates can also prevent the aggregation and precipitation of proteins in injectable formulations.

In addition to their use in pharmaceuticals, polysorbates are also used as emulsifiers in food products such as ice cream, salad dressings, and baked goods. They help to mix oil and water-based ingredients together and prevent them from separating. In cosmetics, polysorbates are used as surfactants, solubilizers, and stabilizers in a variety of personal care products.

It is important to note that some people may have allergic reactions to polysorbates, particularly those with sensitivities to sorbitol or other ingredients used in their production. Therefore, it is essential to carefully consider the potential risks and benefits of using products containing polysorbates in individuals who may be at risk for adverse reactions.

Humoral immunity is a type of immune response in which the body produces proteins called antibodies that circulate in bodily fluids such as blood and help to protect against infection. This form of immunity involves the interaction between antigens (foreign substances that trigger an immune response) and soluble factors, including antibodies, complement proteins, and cytokines.

When a pathogen enters the body, it is recognized as foreign by the immune system, which triggers the production of specific antibodies to bind to and neutralize or destroy the pathogen. These antibodies are produced by B cells, a type of white blood cell that is part of the adaptive immune system.

Humoral immunity provides protection against extracellular pathogens, such as bacteria and viruses, that exist outside of host cells. It is an important component of the body's defense mechanisms and plays a critical role in preventing and fighting off infections.

A Brucella vaccine is a type of immunization used to protect against brucellosis, an infectious disease caused by bacteria of the genus Brucella. The most commonly used vaccine is the Brucella melitensis Rev-1 strain, which is administered to sheep and goats to prevent the spread of the disease to humans through contaminated food and animal contact.

The Brucella vaccine works by stimulating the immune system to produce a protective response against the bacteria. When the vaccinated animal encounters the actual bacterial infection, their immune system is better prepared to fight it off and prevent the development of clinical disease.

It's important to note that the Brucella vaccine is not approved for use in humans due to the risk of severe side effects and the possibility of causing a false positive result on brucellosis diagnostic tests. Therefore, it should only be administered to animals under the supervision of a veterinarian.

Tetanus toxoid is a purified and inactivated form of the tetanus toxin, which is derived from the bacterium Clostridium tetani. It is used as a vaccine to induce active immunity against tetanus, a potentially fatal disease caused by this toxin. The toxoid is produced through a series of chemical treatments that modify the toxic properties of the tetanus toxin while preserving its antigenic qualities. This allows the immune system to recognize and develop protective antibodies against the toxin without causing illness. Tetanus toxoid is often combined with diphtheria and/or pertussis toxoids in vaccines such as DTaP, Tdap, and Td.

Herpesvirus vaccines are immunizations designed to protect against infections caused by herpesviruses. These viruses include herpes simplex virus type 1 (HSV-1), which primarily causes oral herpes, and herpes simplex virus type 2 (HSV-2), which primarily causes genital herpes. Additionally, other herpesviruses such as varicella-zoster virus (VZV), which causes chickenpox and shingles, and cytomegalovirus (CMV), which can cause serious complications in newborns and immunocompromised individuals, are also targeted by herpesvirus vaccines.

Herpesvirus vaccines work by exposing the immune system to a weakened or inactivated form of the virus, or to specific viral proteins, which triggers an immune response. This response includes the production of antibodies and activation of T-cells that recognize and attack the virus if it enters the body in the future.

Currently, there are vaccines available for HSV-1 and HSV-2, but they are not widely used. The only FDA-approved herpesvirus vaccine is for VZV, which is marketed as Varivax and prevents chickenpox and reduces the risk of shingles. There are also several experimental vaccines in development for other herpesviruses, including HSV-1, HSV-2, and CMV.

An "injection, intradermal" refers to a type of injection where a small quantity of a substance is introduced into the layer of skin between the epidermis and dermis, using a thin gauge needle. This technique is often used for diagnostic or research purposes, such as conducting allergy tests or administering immunizations in a way that stimulates a strong immune response. The injection site typically produces a small, raised bump (wheal) that disappears within a few hours. It's important to note that intradermal injections should be performed by trained medical professionals to minimize the risk of complications.

Leishmaniasis vaccines do not currently exist for human use, despite extensive research efforts. However, the concept and goal of a leishmaniasis vaccine refer to a potential prophylactic treatment that would prevent or significantly reduce the risk of contracting Leishmania infections, which cause various clinical manifestations of the disease.

Leishmaniasis is a vector-borne neglected tropical disease caused by protozoan parasites of the Leishmania genus, transmitted through the bite of infected female sandflies. The disease has diverse clinical presentations, ranging from self-healing cutaneous lesions (localized cutaneous leishmaniasis) to destructive mucocutaneous forms (mucocutaneous leishmaniasis) and potentially fatal visceral leishmaniasis, also known as kala-azar.

The development of an effective vaccine against Leishmania infections is challenging due to the complexity of the parasite's life cycle, genetic diversity, and the variety of clinical outcomes it can cause. Several vaccine candidates have been investigated, primarily focusing on inducing cell-mediated immunity, particularly a Th1 response. These candidates include:

1. First-generation vaccines: These are whole-parasite or live-attenuated vaccines, such as Leishmania major (Lm) strain Friedlin and Leishmania tarentolae. Although these vaccines have shown promising results in animal models, their use in humans is limited due to safety concerns.
2. Second-generation vaccines: These involve subunit or recombinant protein vaccines, which utilize specific antigens from the parasite to stimulate an immune response. Examples include Leishmania antigens such as Leishmania major stress-inducible protein 1 (LiSP1), Leishmania donovani A2, and Leishmania infantum nucleoside hydrolase (LiNH36).
3. Third-generation vaccines: These are DNA or RNA/mRNA vaccines that encode specific antigens from the parasite to stimulate an immune response. Examples include plasmid DNA vaccines encoding Leishmania major HSP70 and Leishmania donovani A2.
4. Adjuvant systems: To enhance the immunogenicity of these vaccine candidates, various adjuvants are being explored, such as saponins (QS-21), cytokines (GM-CSF), and TLR agonists (CpG oligodeoxynucleotides).

Despite significant progress in developing Leishmania vaccines, no licensed vaccine is currently available for human use. Further research is required to optimize the formulation, delivery, and safety of these vaccine candidates to ensure their effectiveness against various Leishmania species and clinical manifestations.

Aluminum hydroxide is a medication that contains the active ingredient aluminum hydroxide, which is an inorganic compound. It is commonly used as an antacid to neutralize stomach acid and relieve symptoms of acid reflux and heartburn. Aluminum hydroxide works by reacting with the acid in the stomach to form a physical barrier that prevents the acid from backing up into the esophagus.

In addition to its use as an antacid, aluminum hydroxide is also used as a phosphate binder in patients with kidney disease. It works by binding to phosphate in the gut and preventing it from being absorbed into the bloodstream, which can help to control high phosphate levels in the body.

Aluminum hydroxide is available over-the-counter and by prescription in various forms, including tablets, capsules, and liquid suspensions. It is important to follow the dosage instructions carefully and to talk to a healthcare provider if symptoms persist or worsen.

'Influenza A Virus, H1N1 Subtype' is a specific subtype of the influenza A virus that causes flu in humans and animals. It contains certain proteins called hemagglutinin (H) and neuraminidase (N) on its surface, with this subtype specifically having H1 and N1 antigens. The H1N1 strain is well-known for causing the 2009 swine flu pandemic, which was a global outbreak of flu that resulted in significant morbidity and mortality. This subtype can also cause seasonal flu, although the severity and symptoms may vary. It is important to note that influenza viruses are constantly changing, and new strains or subtypes can emerge over time, requiring regular updates to vaccines to protect against them.

Alum compounds are a type of double sulfate salt, typically consisting of aluminum sulfate and another metal sulfate. The most common variety is potassium alum, or potassium aluminum sulfate (KAl(SO4)2·12H2O). Alum compounds have a wide range of uses, including water purification, tanning leather, dyeing and printing textiles, and as a food additive for baking powder and pickling. They are also used in medicine as astringents to reduce bleeding and swelling, and to soothe skin irritations. Alum compounds have the ability to make proteins in living cells become more stable, which can be useful in medical treatments.

Immunotherapy List of vaccine ingredients List of vaccine topics Virosome "Selecting Viruses for the Seasonal Influenza Vaccine ... doi:10.1038/459144a Vaccines and Antisera at Curlie WHO Vaccine preventable diseases and immunization The History of Vaccines, ... Vaccine viruses are chosen to maximize the likelihood that the vaccine will protect against the viruses most likely to spread ... WHO recommends specific vaccine viruses for influenza vaccine production, but then individual countries make their own ...
List of vaccine ingredients List of vaccine topics Reverse vaccinology Virosome Immunity Keller H, Glueck R, Wegmann A et al. ... 1-21 Vaccines and Antisera at Curlie WHO Vaccine preventable diseases and immunization The History of Vaccines, from the ... Purified duck embryo vaccine (PDEV) was the first vaccine developed for human use in treating pre- and postexposure to the ... However, newer vaccines are more commonly used. These include the human diploid cell vaccine (HDCV) first introduced in 1978; ...
"The virosome concept for influenza vaccines". Vaccine. 23: S26-38. doi:10.1016/j.vaccine.2005.04.026. PMID 16026906. Bomsel M, ... If the virosome is administered into the bloodstream, the virosome can disintegrate. However, if the virosome can reach the ... A virosome is a drug or vaccine delivery mechanism consisting of unilamellar phospholipid membrane (either a mono- or bi-layer ... "What are virosomes?" "Virosome based vaccine" (Articles with short description, Short description is different from Wikidata, ...
... vaccines, dna MeSH D23.050.865.915 - vaccines, edible MeSH D23.050.865.940 - vaccines, virosome MeSH D23.101.100.110 - antigens ...
... vaccines OPV AIDS hypothesis Preventive healthcare Reverse vaccinology TA-CD Timeline of vaccines Virosome Vaccinator Vaccine ... The subgroup of genetic vaccines encompass viral vector vaccines, RNA vaccines and DNA vaccines. Viral vector vaccines use a ... Examples include IPV (polio vaccine), hepatitis A vaccine, rabies vaccine and most influenza vaccines. Toxoid vaccines are made ... RNA vaccines and DNA vaccines are examples of third generation vaccines. In 2016 a DNA vaccine for the Zika virus began testing ...
Vaccine Polio vaccine List of vaccine ingredients List of vaccine topics Virosome Das, Razib; Mishra, Pravin; Jha, Rajesh (2021 ... In human vaccine development, the main advantage is rapid propagation, and high yield, of viruses for vaccine production. This ... both attenuated vaccine and inactivated vaccine forms. It is recommended by the World Health Organization in managing influenza ... In medical usage it refers to the growth of live virus in chicken egg embryos for vaccine development for human use, as well as ...
Mymetics is developing a pre-clinical preventative vaccine for HSV 1 and 2 using its virosome technology. There has not been ... Below is a list of vaccines that are no longer being pursued. One vaccine that was under trial was Herpevac, a vaccine against ... Profectus BioSciences intends to use its PBS Vax therapeutic vaccine technology to engineer a vaccine for HSV-2. The vaccine is ... Vaccine. 36 (20): 2842-2849. doi:10.1016/j.vaccine.2018.03.075. PMID 29655629. "Herpes Virus Mutant Points Towards New Vaccine ...
... vaccines, dna MeSH D20.215.894.865.915 - vaccines, edible MeSH D20.215.894.865.940 - vaccines, virosome MeSH D20.215.894.899 - ... hepatitis a vaccines MeSH D20.215.894.899.955.400 - hepatitis b vaccines MeSH D20.215.894.899.970 - yellow fever vaccine MeSH ... measles vaccine MeSH D20.215.894.899.404.500 - measles-mumps-rubella vaccine MeSH D20.215.894.899.488 - mumps vaccine MeSH ... rubella vaccine MeSH D20.215.894.899.779.500 - measles-mumps-rubella vaccine MeSH D20.215.894.899.790 - saids vaccines MeSH ...
Services, U.S. Department of Health and Human (26 April 2021). "Vaccines.gov". www.vaccines.gov. "Cancer Vaccines and Their ... Cancer Gene therapy Oncolytic virus Vector Virosome, using modified viruses for drug delivery Dog parasite press article ... Rather than preventing causes of cancer, as one would traditionally think in the context of vaccines, vaccines against cancer ... Unlike traditional vaccines, in which attenuated or killed virus/bacteria is used to generate an immune response, viral ...
Pox lesion formation around the vaccination area is indicative that the vaccine has been effective. The vaccine should not be ... virosome'. Furthermore, gene expression is divided into three phases: early, intermediate and late. At each stage specific ... and some birds needed another vaccine as the first vaccine did not work. Therefore, a range of symptoms can be observed in a ... The vaccines typically use the CNPV ALVAC strain, which is highly attenuated. The use of this strain has been involved in the ...
They can be used for vaccines (VACCINES, VIROSOME), drug delivery, or gene transfer. ...
Immunotherapy List of vaccine ingredients List of vaccine topics Virosome "Selecting Viruses for the Seasonal Influenza Vaccine ... doi:10.1038/459144a Vaccines and Antisera at Curlie WHO Vaccine preventable diseases and immunization The History of Vaccines, ... Vaccine viruses are chosen to maximize the likelihood that the vaccine will protect against the viruses most likely to spread ... WHO recommends specific vaccine viruses for influenza vaccine production, but then individual countries make their own ...
Mymetics delivers malaria antigens through a particle called a "virosome," which is essentially an empty, non-infectious virus ... While media coverage of the flu vaccine has become a seasonal commonplace, vaccines are currently being sought for many modern ... Sylvain Fleury, chief scientific officer at Mymetics, a Swiss vaccine biotech currently developing a vaccine with the potential ... scientific approach to vaccine development, and described the companys development-stage vaccine candidates as "exciting." ...
Open the PDF for Development of a Virosome Vaccine Against Avian Metapneumovirus Subtype C for Protection in Turkeys in another ... Development of a Virosome Vaccine Against Avian Metapneumovirus Subtype C for Protection in Turkeys ... Open the PDF for Development of a Virosome Vaccine for Newcastle Disease Virus in another window ... View article titled, Development of a Virosome Vaccine Against Avian Metapneumovirus Subtype C for Protection in Turkeys ...
NPJ vaccines. Amacker M,Smardon C,Mason L,Sorrell J,Jeffery K,Adler M,Bhoelan F,Belova O,Spengler M,Punnamoottil B,Schwaller M, ... 2 In vitro virosome toxicity and uptake by antigen-presenting cells. a Human CD34 + -derived cells in culture were exposed to ... The stronger is the fluorescent Atto 647 signal, the more virosome uptake took place. The percentage of Atto 647 positive cells ... suggesting that excipients did not interfere with early virosome uptake by APC. Data are from a representative experiment.. ...
Pérez OM, Herzog C, Zellmeyer M, Loáisiga A, Frösner G, Egger M. Efficacy of virosome hepatitis A vaccine in young children in ... vaccine and varicella vaccine) when administered either as individual or combination vaccines. Administration of MMR should be ... Vaccine Storage and Shipment Hepatitis A vaccine should be stored and shipped at temperatures ranging from 35.6°F--46.4°F (2°C ... Hepatitis A Vaccine Inactivated and attenuated hepatitis A vaccines have been developed and evaluated in human clinical trials ...
VACCINES, VIROSOME. VACUNAS DE VIROSOMA. VACINAS VIROSSOMAIS. VALIDATION STUDIES [PUBLICATION TYPE]. ESTUDIOS DE VALIDACION [ ... VACCINES, EDIBLE. VACUNAS COMESTIBLES. VACINAS DE PLANTAS COMESTÍVEIS. VACCINES, MARKER. VACUNAS MARCADORAS. VACINAS MARCADORAS ... PNEUMOCOCCAL VACCINES. VACUNAS NEUMOCOCICAS. VACINAS PNEUMOCÓCICAS. POLIOVIRUS VACCINES. VACUNAS CONTRA POLIOVIRUS. VACINAS ... VACCINES, ACELLULAR. VACUNAS ACELULARES. VACINAS ACELULARES. VACCINES, CONTRACEPTIVE. VACUNAS ANTICONCEPTIVAS. VACINAS ...
VACCINES, VIROSOME. VACUNAS DE VIROSOMA. VACINAS VIROSSOMAIS. VALIDATION STUDIES [PUBLICATION TYPE]. ESTUDIOS DE VALIDACION [ ... VACCINES, EDIBLE. VACUNAS COMESTIBLES. VACINAS DE PLANTAS COMESTÍVEIS. VACCINES, MARKER. VACUNAS MARCADORAS. VACINAS MARCADORAS ... PNEUMOCOCCAL VACCINES. VACUNAS NEUMOCOCICAS. VACINAS PNEUMOCÓCICAS. POLIOVIRUS VACCINES. VACUNAS CONTRA POLIOVIRUS. VACINAS ... VACCINES, ACELLULAR. VACUNAS ACELULARES. VACINAS ACELULARES. VACCINES, CONTRACEPTIVE. VACUNAS ANTICONCEPTIVAS. VACINAS ...
VACCINES, VIROSOME. VACUNAS DE VIROSOMA. VACINAS VIROSSOMAIS. VALIDATION STUDIES [PUBLICATION TYPE]. ESTUDIOS DE VALIDACION [ ... VACCINES, EDIBLE. VACUNAS COMESTIBLES. VACINAS DE PLANTAS COMESTÍVEIS. VACCINES, MARKER. VACUNAS MARCADORAS. VACINAS MARCADORAS ... PNEUMOCOCCAL VACCINES. VACUNAS NEUMOCOCICAS. VACINAS PNEUMOCÓCICAS. POLIOVIRUS VACCINES. VACUNAS CONTRA POLIOVIRUS. VACINAS ... VACCINES, ACELLULAR. VACUNAS ACELULARES. VACINAS ACELULARES. VACCINES, CONTRACEPTIVE. VACUNAS ANTICONCEPTIVAS. VACINAS ...
VACCINES, VIROSOME. VACUNAS DE VIROSOMA. VACINAS VIROSSOMAIS. VALIDATION STUDIES [PUBLICATION TYPE]. ESTUDIOS DE VALIDACION [ ... VACCINES, EDIBLE. VACUNAS COMESTIBLES. VACINAS DE PLANTAS COMESTÍVEIS. VACCINES, MARKER. VACUNAS MARCADORAS. VACINAS MARCADORAS ... PNEUMOCOCCAL VACCINES. VACUNAS NEUMOCOCICAS. VACINAS PNEUMOCÓCICAS. POLIOVIRUS VACCINES. VACUNAS CONTRA POLIOVIRUS. VACINAS ... VACCINES, ACELLULAR. VACUNAS ACELULARES. VACINAS ACELULARES. VACCINES, CONTRACEPTIVE. VACUNAS ANTICONCEPTIVAS. VACINAS ...
VACCINES, VIROSOME. VACUNAS DE VIROSOMA. VACINAS VIROSSOMAIS. VALIDATION STUDIES [PUBLICATION TYPE]. ESTUDIOS DE VALIDACION [ ... VACCINES, EDIBLE. VACUNAS COMESTIBLES. VACINAS DE PLANTAS COMESTÍVEIS. VACCINES, MARKER. VACUNAS MARCADORAS. VACINAS MARCADORAS ... PNEUMOCOCCAL VACCINES. VACUNAS NEUMOCOCICAS. VACINAS PNEUMOCÓCICAS. POLIOVIRUS VACCINES. VACUNAS CONTRA POLIOVIRUS. VACINAS ... VACCINES, ACELLULAR. VACUNAS ACELULARES. VACINAS ACELULARES. VACCINES, CONTRACEPTIVE. VACUNAS ANTICONCEPTIVAS. VACINAS ...
VACCINES, VIROSOME. VACUNAS DE VIROSOMA. VACINAS VIROSSOMAIS. VALIDATION STUDIES [PUBLICATION TYPE]. ESTUDIOS DE VALIDACION [ ... VACCINES, EDIBLE. VACUNAS COMESTIBLES. VACINAS DE PLANTAS COMESTÍVEIS. VACCINES, MARKER. VACUNAS MARCADORAS. VACINAS MARCADORAS ... PNEUMOCOCCAL VACCINES. VACUNAS NEUMOCOCICAS. VACINAS PNEUMOCÓCICAS. POLIOVIRUS VACCINES. VACUNAS CONTRA POLIOVIRUS. VACINAS ... VACCINES, ACELLULAR. VACUNAS ACELULARES. VACINAS ACELULARES. VACCINES, CONTRACEPTIVE. VACUNAS ANTICONCEPTIVAS. VACINAS ...
VACCINES, VIROSOME. VACUNAS DE VIROSOMA. VACINAS VIROSSOMAIS. VALIDATION STUDIES [PUBLICATION TYPE]. ESTUDIOS DE VALIDACION [ ... VACCINES, EDIBLE. VACUNAS COMESTIBLES. VACINAS DE PLANTAS COMESTÍVEIS. VACCINES, MARKER. VACUNAS MARCADORAS. VACINAS MARCADORAS ... PNEUMOCOCCAL VACCINES. VACUNAS NEUMOCOCICAS. VACINAS PNEUMOCÓCICAS. POLIOVIRUS VACCINES. VACUNAS CONTRA POLIOVIRUS. VACINAS ... VACCINES, ACELLULAR. VACUNAS ACELULARES. VACINAS ACELULARES. VACCINES, CONTRACEPTIVE. VACUNAS ANTICONCEPTIVAS. VACINAS ...
VACCINES, VIROSOME. VACUNAS DE VIROSOMA. VACINAS VIROSSOMAIS. VALIDATION STUDIES [PUBLICATION TYPE]. ESTUDIOS DE VALIDACION [ ... VACCINES, EDIBLE. VACUNAS COMESTIBLES. VACINAS DE PLANTAS COMESTÍVEIS. VACCINES, MARKER. VACUNAS MARCADORAS. VACINAS MARCADORAS ... PNEUMOCOCCAL VACCINES. VACUNAS NEUMOCOCICAS. VACINAS PNEUMOCÓCICAS. POLIOVIRUS VACCINES. VACUNAS CONTRA POLIOVIRUS. VACINAS ... VACCINES, ACELLULAR. VACUNAS ACELULARES. VACINAS ACELULARES. VACCINES, CONTRACEPTIVE. VACUNAS ANTICONCEPTIVAS. VACINAS ...
VACCINES, VIROSOME. VACUNAS DE VIROSOMA. VACINAS VIROSSOMAIS. VALIDATION STUDIES [PUBLICATION TYPE]. ESTUDIOS DE VALIDACION [ ... VACCINES, EDIBLE. VACUNAS COMESTIBLES. VACINAS DE PLANTAS COMESTÍVEIS. VACCINES, MARKER. VACUNAS MARCADORAS. VACINAS MARCADORAS ... PNEUMOCOCCAL VACCINES. VACUNAS NEUMOCOCICAS. VACINAS PNEUMOCÓCICAS. POLIOVIRUS VACCINES. VACUNAS CONTRA POLIOVIRUS. VACINAS ... VACCINES, ACELLULAR. VACUNAS ACELULARES. VACINAS ACELULARES. VACCINES, CONTRACEPTIVE. VACUNAS ANTICONCEPTIVAS. VACINAS ...
VACCINES, VIROSOME. VACUNAS DE VIROSOMA. VACINAS VIROSSOMAIS. VALIDATION STUDIES [PUBLICATION TYPE]. ESTUDIOS DE VALIDACION [ ... VACCINES, EDIBLE. VACUNAS COMESTIBLES. VACINAS DE PLANTAS COMESTÍVEIS. VACCINES, MARKER. VACUNAS MARCADORAS. VACINAS MARCADORAS ... PNEUMOCOCCAL VACCINES. VACUNAS NEUMOCOCICAS. VACINAS PNEUMOCÓCICAS. POLIOVIRUS VACCINES. VACUNAS CONTRA POLIOVIRUS. VACINAS ... VACCINES, ACELLULAR. VACUNAS ACELULARES. VACINAS ACELULARES. VACCINES, CONTRACEPTIVE. VACUNAS ANTICONCEPTIVAS. VACINAS ...
VACCINES, VIROSOME. VACUNAS DE VIROSOMA. VACINAS VIROSSOMAIS. VALIDATION STUDIES [PUBLICATION TYPE]. ESTUDIOS DE VALIDACION [ ... VACCINES, EDIBLE. VACUNAS COMESTIBLES. VACINAS DE PLANTAS COMESTÍVEIS. VACCINES, MARKER. VACUNAS MARCADORAS. VACINAS MARCADORAS ... PNEUMOCOCCAL VACCINES. VACUNAS NEUMOCOCICAS. VACINAS PNEUMOCÓCICAS. POLIOVIRUS VACCINES. VACUNAS CONTRA POLIOVIRUS. VACINAS ... VACCINES, ACELLULAR. VACUNAS ACELULARES. VACINAS ACELULARES. VACCINES, CONTRACEPTIVE. VACUNAS ANTICONCEPTIVAS. VACINAS ...
VACCINES, VIROSOME. VACUNAS DE VIROSOMA. VACINAS VIROSSOMAIS. VALIDATION STUDIES [PUBLICATION TYPE]. ESTUDIOS DE VALIDACION [ ... VACCINES, EDIBLE. VACUNAS COMESTIBLES. VACINAS DE PLANTAS COMESTÍVEIS. VACCINES, MARKER. VACUNAS MARCADORAS. VACINAS MARCADORAS ... PNEUMOCOCCAL VACCINES. VACUNAS NEUMOCOCICAS. VACINAS PNEUMOCÓCICAS. POLIOVIRUS VACCINES. VACUNAS CONTRA POLIOVIRUS. VACINAS ... VACCINES, ACELLULAR. VACUNAS ACELULARES. VACINAS ACELULARES. VACCINES, CONTRACEPTIVE. VACUNAS ANTICONCEPTIVAS. VACINAS ...
A SARS-CoV-2 Wuhan spike virosome vaccine induces superior neutralization breadth compared to one using the Beta spike. van der ... NPJ vaccines. 6, 1, 146.. Research output: Contribution to journal › Article › Academic › peer-review ...
The influenza virosome vaccine elicited hemagglutinin-specific antibodies.... Tipo: Artigo de periódico. Palavras-chave: ... Methods: This study evaluated the immunogenicity of a virosome-based influenza vaccine containing the surface glycoproteins of ... Results: A robust humoral and cellular immune response was induced against the three IAV subtypes in pigs after two vaccine ... Virosomes are virus-like particles that mimic virus infection and have proven to be a successful vaccine platform against ...
CONCLUSIONS: This virosome platform allows flexibility to adjust the vaccine content to reflect the diversity of circulating ... The influenza virosome vaccine elicited hemagglutinin-specific antibodies and virus-neutralizing activity. Furthermore, it ... METHODS: This study evaluated the immunogenicity of a virosome-based influenza vaccine containing the surface glycoproteins of ... Also, the vaccine demonstrated potential to confer long-lasting immunity until the market age of pigs and proved to be safe and ...
Taken together, our results indicate that LV vectors can serve to design pDC-based vaccines in humans, and they are also useful ... Gene transfer into pDC could be of high importance for the design of new DC-based vaccines, or for induction of peripheral ... Angel J, Chaperot L, Molens JP, Mezin P, Amacker M, Zurbriggen R, Grichine A, Plumas J: Virosome-mediated delivery of tumor ... Taken together, our results indicate that LV vectors can serve to design pDC-based vaccines in humans, and they are also useful ...
"Virosome-formulated Plasmodium falciparum AMA-1 & CSP derived peptides as malaria vaccine: randomized phase 1b trial in semi- ... "The malaria vaccine development program in Papua New Guinea." Trends Parasitol. 19, no. 6 (2003): 264-270. ... "Safety and immunogenicity of a three-component blood-stage malaria vaccine (MSP1, MSP2, RESA) against Plasmodium falciparum in ... "A recombinant blood-stage malaria vaccine reduces Plasmodium falciparum density and exerts selective pressure on parasite ...
... a pioneer and leader in the research and development of virosome-based vaccines, and Anergis SA, a company developing ... a pioneer and leader in the research and development of virosome-based vaccines, and Anergis SA, a company developing ...
... a pioneering company at the forefront of the development of virosome-based vaccines. The MACIVIVA goal was to develop dry ... monoclonal antibodies and vaccines). A key … Read more ...
PNEUMOCOCCAL VACCINES. VACUNAS NEUMOCOCICAS. VACINAS VIROSSOMAIS. VACCINES, VIROSOME. VACUNAS DE VIROSOMA. VENTILAÇÃO LÍQUIDA. ... DIPHTHERIA-TETANUS VACCINE. VACUNA CONTRA DIFTERIA-TETANO. VACINA CONTRA FEBRE AMARELA. YELLOW FEVER VACCINE. VACUNA CONTRA LA ... LYME DISEASE VACCINES. VACUNAS CONTRA ENFERMEDAD DE LYME. VACINAS CONTRA DOENÇA DE MAREK. MAREK DISEASE VACCINES. VACUNAS ... ESCHERICHIA COLI VACCINES. VACUNAS CONTRA ESCHERICHIA COLI. VACINAS CONTRA HEPATITE A. HEPATITIS A VACCINES. VACUNAS CONTRA LA ...
Current methods for identification and / or quantification of viral proteins of influenza virus and suffer virosome sample long ... electrophoresis method for fast and accurate identification and quantification of multiple viral proteins in influenza vaccines ... electrophoresis method for fast and accurate identification and quantification of multiple viral proteins in influenza vaccines ... electrophoresis method for fast and accurate identification and quantification of multiple viral proteins in influenza vaccines ...
Current methods for identification and / or quantification of viral proteins of influenza virus and suffer virosome sample long ... electrophoresis method for fast and accurate identification and quantification of multiple viral proteins in influenza vaccines ... electrophoresis method for fast and accurate identification and quantification of multiple viral proteins in influenza vaccines ... electrophoresis method for fast and accurate identification and quantification of multiple viral proteins in influenza vaccines ...
In a secondary analysis of RV144, plasma IgA decreased the in vitro ADCC activity of vaccine-induced, Env-specific IgG with the ... In a vaccine efficacy study, in which virosomes displaying HIV gp41 antigens protected most rhesus monkeys (RMs) against simian ... Inhibition of transcytosis by a primary HIV clade C strain implied that the combined virosome immunogens displaying either ... Vaccine-induced mucosal IgA responses can also block HIV or SHIV infection after mucosal exposure (Figure 3B). Plasma cells in ...
  • Virosomes are virus-like particles that mimic virus infection and have proven to be a successful vaccine platform against several animal and human viruses. (embrapa.br)
  • In a vaccine efficacy study, in which virosomes displaying HIV gp41 antigens protected most rhesus monkeys (RMs) against simian-human immunodeficiency virus (SHIV), protection correlated with vaginal IgA capable of blocking HIV transcytosis in vitro. (biomedcentral.com)
  • Killed and live influenza virus vaccines are effective in 361/2002 viruses. (cdc.gov)
  • Finally, universal influenza virus vaccines seem to 2002, and instead again used the same strain as in the 2002 be within reach. (cdc.gov)
  • Because of this bureaucratic roadblock, the H3N2 substantial contamination by egg-derived components, component of the 2003-2004 influenza virus vaccine was these killed (formaldehyde-treated) vaccines were highly antigenically "off" and showed suboptimal efficacy. (cdc.gov)
  • To this day, it priate seed strains makes the yearly process of remains the basis for the manufacturing process of our manufacturing influenza virus vaccines unnecessarily influenza virus vaccines. (cdc.gov)
  • Despite the obvious efficacy of both killed and live obtained from the allantoic fluid of 1 infected embryonat- influenza virus vaccines, there is room for new develop- ed egg. (cdc.gov)
  • Epalinges, Switzerland, April 23, 2018 - Mymetics Corporation (OTCQB:MYMX), a pioneer and leader in the research and development of virosome-based vaccines, and Anergis SA, a company developing Contiguous Overlapping Peptides (COPs) for ultra-fast allergy immunotherapy, announced today that Mymetics SA, the Swiss subsidiary of Mymetics Corporation and Anergis SA have entered into a Research Collaboration project. (mymetics.com)
  • Spray drying is becoming increasingly viewed as a more cost-effective method for enhancing the stability of thermo-sensitive molecules (such as proteins, peptides, monoclonal antibodies and vaccines). (upperton.com)
  • Health Organization publishes semiannual recommenda- ing vaccine seed viruses. (cdc.gov)
  • Also, because the cumbersome clas- poses, revolutionized the purification process and industri- sical reassortment technique used for preparing the appro- al production of many viruses for vaccines. (cdc.gov)
  • Vaccine viruses are chosen to maximize the likelihood that the vaccine will protect against the viruses most likely to spread and cause illness among people during the upcoming flu season. (wikipedia.org)
  • WHO recommends specific vaccine viruses for influenza vaccine production, but then individual countries make their own decisions for licensing of vaccines in their country. (wikipedia.org)
  • In the United States, the Food and Drug Administration determines what viruses will be used in U.S.-licensed vaccines. (wikipedia.org)
  • Methods: This study evaluated the immunogenicity of a virosome-based influenza vaccine containing the surface glycoproteins of H1N1 pandemic, H1N2 and H3N2 in pigs. (embrapa.br)
  • Taken together, our results indicate that LV vectors can serve to design pDC-based vaccines in humans, and they are also useful in vitro to evaluate the immunogenicity of the vector preparations, and the specificity and safety of given promoters used in gene therapy protocols. (biomedcentral.com)
  • For example, in 2003 FDA rejected the killed and live vaccines, increasing the number of available use of the most appropriate H3N2 strain, A/Fujian/411/ doses. (cdc.gov)
  • Results: A robust humoral and cellular immune response was induced against the three IAV subtypes in pigs after two vaccine doses. (embrapa.br)
  • The World Health Organization (WHO) reports that licensed vaccines are currently available for twenty-five different preventable infections . (webot.org)
  • In season, vaccine efficacy climbs to 82% to 100% ( 7 ). (cdc.gov)
  • Abstract: Background: Influenza A virus (IAV) is endemic in pigs globally and co-circulation of genetically and antigenically diverse virus lineages of subtypes H1N1, H1N2 and H3N2 is a challenge for the development of effective vaccines. (embrapa.br)
  • Also, the vaccine demonstrated potential to confer long-lasting immunity until the market age of pigs and proved to be safe and non-cytotoxic to pigs. (bvsalud.org)
  • In a secondary analysis of RV144, plasma IgA decreased the in vitro ADCC activity of vaccine-induced, Env-specific IgG with the same epitope specificity. (biomedcentral.com)
  • Cloning, expression and in vitro validation of chimeric multi epitope vaccine candidate against visceral leishmaniasis infection. (du.ac.in)
  • Since licensure of hepatitis A vaccine during 1995--1996, the hepatitis A childhood immunization strategy has been implemented incrementally, starting with the recommendation of the Advisory Committee on Immunization Practices (ACIP) in 1996 to vaccinate children living in communities with the highest disease rates and continuing in 1999 with ACIP's recommendations for vaccination of children living in states, counties, and communities with consistently elevated hepatitis A rates. (cdc.gov)
  • Forty-one percent of the human race lives in areas of high malaria transmission," says Dr. Sylvain Fleury, chief scientific officer at Mymetics, a Swiss vaccine biotech currently developing a vaccine with the potential to control malaria in developing countries. (infectioncontroltoday.com)
  • Professor Odile Mercereau-Puijalon, of the Pasteur Institute in Paris, and a member of the malaria scientific board of the Gates Foundation, wrote that he was "impressed" by Mymetics' scientific approach to vaccine development, and described the company's development-stage vaccine candidates as "exciting. (infectioncontroltoday.com)
  • Mymetics delivers malaria antigens through a particle called a "virosome," which is essentially an empty, non-infectious virus particle. (infectioncontroltoday.com)
  • Other technologic break- vaccine. (cdc.gov)
  • Furthermore, Mymetics' vaccine design combines both this cutting-edge technologic platform and an innovative antigen engineering that minimizes human protein homologies in order to avoid any potential autoimmune developments. (infectioncontroltoday.com)
  • [3] [4] A vaccine typically contains an agent that resembles a disease-causing microorganism and is often made from weakened or killed forms of the microbe, its toxins, or one of its surface proteins . (webot.org)
  • Live virus reference strain (LVRS) refers to a common strain of a virus that is selected for the manufacture of a preventative vaccine.st commonly used in reference to the seasonal Influenza vaccines developed by the Centers for Disease Control every year. (wikipedia.org)
  • While media coverage of the flu vaccine has become a seasonal commonplace, vaccines are currently being sought for many modern large-scale epidemics. (infectioncontroltoday.com)
  • News 22nd January 2019 - Successful completion of EU Horizon 2020 Grant MACIVIVA In 2014, Upperton Pharma Solutions was awarded a prestigious Horizon 2020 MACIVIVA grant as part of a European consortium led by Mymetics, a pioneering company at the forefront of the development of virosome-based vaccines. (upperton.com)
  • [17] The science of vaccine development and production is termed vaccinology . (webot.org)
  • A vaccine is a biological preparation that provides active acquired immunity to a particular infectious or malignant disease. (webot.org)
  • New capillary gel electrophoresis method for fast and accurate identification and quantification of multiple viral proteins in influenza vaccines. (zetabiotech.com)
  • Vaccines can be prophylactic (to prevent or ameliorate the effects of a future infection by a natural or "wild" pathogen ), or therapeutic (to fight a disease that has already occurred, such as cancer ). (webot.org)
  • America saw 1,337 cases, including eight deaths, as recently as 2002 - the importance of developing a vaccine for the disease is becoming more and more urgent. (infectioncontroltoday.com)
  • Infectious diseases before and after a vaccine was introduced. (webot.org)
  • There is overwhelming scientific consensus that vaccines are a very safe and effective way to fight and eradicate infectious diseases. (webot.org)
  • Finally, Fleury stated "We also believe that the vaccine effectiveness will be improved by targeting the different maturation forms of the parasite during the infectious cycle, instead of the classical strategy to target only one of them. (infectioncontroltoday.com)
  • [1] [2] The safety and effectiveness of vaccines has been widely studied and verified. (webot.org)
  • CONCLUSIONS: This virosome platform allows flexibility to adjust the vaccine content to reflect the diversity of circulating IAVs in swine in Brazil. (bvsalud.org)
  • By taking advantage of these tions for the strains to be included for the Northern and new technologies, we could develop live vaccines that would be safe, cross-protective against variant strains, and Southern Hemispheres ( 2 ). (cdc.gov)
  • [25] Sometimes, protection fails for vaccine-related reasons such as failures in vaccine attenuation, vaccination regimens or administration. (webot.org)
  • The administration of vaccines is called vaccination . (webot.org)

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