Archives
Libraries
Analog-Digital Conversion
Radiology Information Systems
Tissue Fixation
Biological Specimen Banks
Paraffin Embedding
National Library of Medicine (U.S.)
Formaldehyde
Access to Information
Publishing
Internet
Libraries, Medical
Database Management Systems
Computer Communication Networks
Information Storage and Retrieval
Tobacco Industry
Databases, Factual
User-Computer Interface
Retrospective Studies
Databases, Nucleic Acid
Biomedical Research
Software
Optimisation of DNA and RNA extraction from archival formalin-fixed tissue. (1/75)
Archival, formalin-fixed, paraffin-embedded tissue is an invaluable resource for molecular genetic studies but the extraction of high quality nucleic acid may be problematic. We have optimised DNA extraction by comparing 10 protocols, including a commercially available kit and a novel method that utilises a thermal cycler. The thermal cycler and Chelex-100 extraction method yielded DNA capable of amplification by PCR from every block and 61% of sections versus 54% using microwave and Chelex-100, 15% with classical xylene-based extraction and 60% of sections using the kit. Successful RNA extraction was observed, by beta-actin amplification, in 83.7% sections for samples treated by the thermal cycler and Chelex-100 method. Thermal cycler and Chelex-100 extraction of nucleic acid is reliable, quick and inexpensive. (+info)Sudden cardiac death with apparently normal heart. (2/75)
BACKGROUND: Mechanisms of sudden cardiac death (SCD) in subjects with apparently normal hearts are poorly understood. In survivors, clinical investigations may not establish normal cardiac structure with certainty. Large autopsy series may provide a unique opportunity to confirm structural normalcy of the heart before reviewing a patient's clinical history. METHODS AND RESULTS: We identified and reexamined structurally normal hearts from a 13-year series of archived hearts of patients who had sudden cardiac death. Subsequently, for each patient with a structurally normal heart, a detailed review of the circumstances of death as well as clinical history was performed. Of 270 archived SCD hearts identified, 190 were male and 80 female (mean age 42 years); 256 (95%) had evidence of structural abnormalities and 14 (5%) were structurally normal. In the group with structurally normal hearts (mean age 35 years), SCD was the first manifestation of disease in 7 (50%) of the 14 cases. In 6 cases, substances were identified in serum at postmortem examination without evidence of drug overdose; 2 of these chemicals have known associations with SCD. On analysis of ECGs, preexcitation was found in 2 cases. Comorbid conditions identified were seizure disorder and obesity (2 cases each). In 6 cases, there were no identifiable conditions associated with SCD. CONCLUSIONS: In 50% of cases of SCD with structurally normal hearts, sudden death was the first manifestation of disease. An approach combining archived heart examinations with detailed review of the clinical history was effective in elucidating potential SCD mechanisms in 57% of cases. (+info)Chromogenic in situ hybridization: a practical alternative for fluorescence in situ hybridization to detect HER-2/neu oncogene amplification in archival breast cancer samples. (3/75)
Determination of HER-2/neu oncogene amplification has become necessary for selection of breast cancer patients for trastuzumab (Herceptin) therapy. Fluorescence in situ hybridization (FISH) is currently regarded as a gold standard method for detecting HER-2/neu amplification, but it is not very practical for routine histopathological laboratories. We evaluated a new modification of in situ hybridization, the chromogenic in situ hybridization (CISH), which enables detection of HER-2/neu gene copies with conventional peroxidase reaction. Archival formalin-fixed paraffin-embedded tumor tissue sections were pretreated (by heating in a microwave oven and using enzyme digestion) and hybridized with a digoxigenin-labeled DNA probe. The probe was detected with anti-digoxigenin fluorescein, anti-fluorescein peroxidase, and diaminobenzidine. Gene copies visualized by CISH could be easily distinguished with a x40 objective in hematoxylin-stained tissue sections. HER-2/neu amplification typically appeared as large peroxidase-positive intranuclear gene copy clusters. CISH and FISH (according to Vysis, made from frozen pulverized tumor samples) correlated well in a series of 157 breast cancers (kappa coefficient, 0.81). The few different classifications were mostly because of low-level amplifications by FISH that were negative by CISH and immunohistochemistry with monoclonal antibody CB-11. We conclude that CISH, using conventional bright-field microscopy in evaluation, is a useful alternative for determination of HER-2/neu amplification in paraffin-embedded tumor samples, especially for confirming the immunohistochemical staining results. (+info)Polymerase chain reaction detection of Kaposi's sarcoma-associated herpesvirus-optimized protocols and their application to myeloma. (4/75)
Since its discovery in 1994, KSHV (also called human herpesvirus-8 or HHV8) has been implicated in a variety of disorders. Although the association of KSHV with Kaposi's sarcoma (KS), primary effusion lymphoma (PEL), and multicentric Castleman's disease has been well established, its presence in some other diseases, such as multiple myeloma, remains controversial. Because most KSHV studies are based on polymerase chain reaction (PCR) analysis, the conflicting data may be attributable to variations in the methods, primer sets, and target sequences selected. To establish an efficient and reliable PCR approach for KSHV detection we designed eight sets of primers to six regions (ORFK1, ORFK2, ORFK9, ORK26, ORF72, and ORF74) of the KSHV genome using appropriate database and software. The detection sensitivity of these primers was carefully assessed and their reliability was strictly validated in a series of positive (15 KS and PEL samples) and negative (16 lymphoid tissues) controls. We found that primer sets to the ORFK9 region showed the highest sensitivity, whereas primer sets to ORFK1 and ORF74 showed the lowest sensitivity. Primer sets to ORFK9, ORF26 and ORF72 regions detected all of the positive cases, whereas other primer sets showed varying detection rates or nonspecific bands. All 16 negative controls were negative with all primer sets. However, six of 16 negative controls became positive when we used nested PCR targeting ORF26. Therefore, multiple target KSHV sequences increase the detection efficiency, while nested PCR protocols are likely to introduce false positivity. Using ORFK9, ORF26 and ORF72 primer sets, we screened bone marrow biopsies from 18 cases of multiple myeloma, and failed to detect any KSHV sequences. This finding supports the conclusion that KSHV is not associated with multiple myeloma. Indeed, our results further confirm that although KSHV is universally present in Kaposi's sarcoma and primary effusion lymphoma, it is not ubiquitious. (+info)Ethics--dental registration in the seventeenth and early eighteenth century. (5/75)
In the histories of dentistry, some mention is made of the licensing of tooth-drawers, and those who provided dental healthcare before the term Dentist started to become general in the late eighteenth and early nineteenth centuries. One of the most striking references to licensing appears in a little piece of doggerel printed under a 1768 print by Dixon after Harris. (+info)The Protein Data Bank: unifying the archive. (6/75)
The Protein Data Bank (PDB; http://www.pdb.org/) is the single worldwide archive of structural data of biological macromolecules. This paper describes the progress that has been made in validating all data in the PDB archive and in releasing a uniform archive for the community. We have now produced a collection of mmCIF data files for the PDB archive (ftp://beta.rcsb.org/pub/pdb/uniformity/data/mmCIF/). A utility application that converts the mmCIF data files to the PDB format (called CIFTr) has also been released to provide support for existing software. (+info)Laser microdissection and gene expression analysis on formaldehyde-fixed archival tissue. (7/75)
BACKGROUND: Analysis of renal biopsies is currently based on histological recognition of typical structural patterns and immunohistological detection of protein expression alterations. Both can be performed using formaldehyde as the tissue fixative. As a consequence of recent advances in molecular medicine, mRNA expression analysis may offer an attractive option to obtain functionally relevant information. However, quantification of mRNA expression in human renal biopsies thus far has not been possible in formaldehyde-fixed tissue. METHODS: The present study evaluated a recently reported mRNA extraction protocol. Using this approach gene expression analysis could be performed on formaldehyde-fixed archival renal tissues by laser microbeam microdissection, laser pressure catapulting and real time reverse transcription-polymerase chain reaction. RESULTS: For an initial feasibility study, the expression of two chemokines (IP-10 and RANTES) in renal transplant rejection was examined. Induction of protein expression in allografts undergoing rejection was demonstrated for both chemokines by immunohistochemistry. The mRNA expression alterations in the defined renal compartments of glomeruli, vessels and tubulointerstitium were quantified using laser microdissection from formaldehyde-fixed, paraffin-embedded or frozen tissue sections. A pronounced increase of mRNA expression compared to controls was demonstrated for IP-10 as well as RANTES with both tissue-processing protocols. CONCLUSIONS: Using formaldehyde as the tissue fixative, information on the disease process can now be obtained by histological, immunohistochemical and gene expression techniques. In the future this may allow the study of activated molecular programs in routine renal biopsies as well as archival tissue samples. (+info)London home for Crick archive. (8/75)
Unprecedented access to the archives of Francis Crick, just before the 50th anniversary next year of his famous paper co-authored with James Watson on the proposed double helix structure of DNA, looks set to go ahead. Nigel Williams reports. (+info)In the context of medicine, "archives" typically refers to the collection and preservation of medical records or documents that are no longer in active use but still need to be retained for legal, historical, or research purposes. These archived materials may include patient records, clinical trial data, hospital reports, correspondence, images, and other forms of documentation. The purpose of maintaining medical archives is to ensure the availability and integrity of this information for future reference, as well as to comply with regulatory requirements related to record-keeping and privacy.
I'm sorry for any confusion, but "Libraries" is not a term that has a medical definition. A library is a collection of sources of information and similar resources, made accessible to a community for reference or borrowing. This can include books, magazines, audio visual materials, and digital resources. If you have any questions related to health or medicine, I'd be happy to try to help answer those!
Analog-digital conversion, also known as analog-to-digital conversion (ADC) or digitization, is the process of converting a continuous physical quantity or analog signal into a discrete numerical representation or digital signal. This process typically involves sampling the analog signal at regular intervals and then quantizing each sample by assigning it to a specific numerical value within a range. The resulting digital signal can be processed, stored, and transmitted more easily than an analog signal. In medical settings, this type of conversion is often used in devices such as electrocardiograms (ECGs) and blood pressure monitors to convert physiological signals into digital data that can be analyzed and interpreted by healthcare professionals.
"History, 19th Century" is not a medical term or concept. It refers to the historical events, developments, and figures related to the 1800s in various fields, including politics, culture, science, and technology. However, if you are looking for medical advancements during the 19th century, here's a brief overview:
The 19th century was a period of significant progress in medicine, with numerous discoveries and innovations that shaped modern medical practices. Some notable developments include:
1. Edward Jenner's smallpox vaccine (1796): Although not strictly within the 19th century, Jenner's discovery laid the foundation for vaccination as a preventive measure against infectious diseases.
2. Germ theory of disease: The work of Louis Pasteur, Robert Koch, and others established that many diseases were caused by microorganisms, leading to the development of antiseptic practices and vaccines.
3. Anesthesia: In 1842, Crawford Long first used ether as an anesthetic during surgery, followed by the introduction of chloroform in 1847 by James Simpson.
4. Antisepsis and asepsis: Joseph Lister introduced antiseptic practices in surgery, significantly reducing postoperative infections. Later, the concept of asepsis (sterilization) was developed to prevent contamination during surgical procedures.
5. Microbiology: The development of techniques for culturing and staining bacteria allowed for better understanding and identification of pathogens.
6. Physiology: Claude Bernard's work on the regulation of internal body functions, or homeostasis, contributed significantly to our understanding of human physiology.
7. Neurology: Jean-Martin Charcot made significant contributions to the study of neurological disorders, including multiple sclerosis and Parkinson's disease.
8. Psychiatry: Sigmund Freud developed psychoanalysis, a new approach to understanding mental illnesses.
9. Public health: The 19th century saw the establishment of public health organizations and initiatives aimed at improving sanitation, water quality, and vaccination programs.
10. Medical education reforms: The Flexner Report in 1910 led to significant improvements in medical education standards and practices.
I'm sorry for any confusion, but "History, 20th Century" is a broad and complex topic that refers to the events, developments, and transformations that occurred throughout the world during the 1900s. It is not a medical term or concept. If you're interested in learning more about this historical period, I would recommend consulting a history textbook, reputable online resources, or speaking with a historian. They can provide detailed information about the political, social, economic, and cultural changes that took place during the 20th century.
A Radiology Information System (RIS) is a type of healthcare software specifically designed to manage medical imaging data and related patient information. It serves as a centralized database and communication platform for radiology departments, allowing the integration, storage, retrieval, and sharing of patient records, orders, reports, images, and other relevant documents.
The primary functions of a RIS typically include:
1. Scheduling and tracking: Managing appointments, scheduling resources, and monitoring workflow within the radiology department.
2. Order management: Tracking and processing requests for imaging exams from referring physicians or other healthcare providers.
3. Image tracking: Monitoring the movement of images throughout the entire imaging process, from acquisition to reporting and storage.
4. Report generation: Assisting radiologists in creating structured, standardized reports based on the interpreted imaging studies.
5. Results communication: Sending finalized reports back to the referring physicians or other healthcare providers, often through integration with electronic health records (EHRs) or hospital information systems (HIS).
6. Data analytics: Providing tools for analyzing and reporting departmental performance metrics, such as turnaround times, equipment utilization, and patient satisfaction.
7. Compliance and security: Ensuring adherence to regulatory requirements related to data privacy, protection, and storage, while maintaining secure access controls for authorized users.
By streamlining these processes, a RIS helps improve efficiency, reduce errors, enhance communication, and support better patient care within radiology departments.
Tissue fixation is a process in histology (the study of the microscopic structure of tissues) where fixed tissue samples are prepared for further examination, typically through microscopy. The goal of tissue fixation is to preserve the original three-dimensional structure and biochemical composition of tissues and cells as much as possible, making them stable and suitable for various analyses.
The most common method for tissue fixation involves immersing the sample in a chemical fixative, such as formaldehyde or glutaraldehyde. These fixatives cross-link proteins within the tissue, creating a stable matrix that maintains the original structure and prevents decay. Other methods of tissue fixation may include freezing or embedding samples in various media to preserve their integrity.
Properly fixed tissue samples can be sectioned, stained, and examined under a microscope, allowing pathologists and researchers to study cellular structures, diagnose diseases, and understand biological processes at the molecular level.
A Biological Specimen Bank, also known as a biobank or tissue bank, is a type of medical facility that collects, stores, and distributes biological samples for research purposes. These samples can include tissues, cells, DNA, blood, and other bodily fluids, and are often collected during medical procedures or from donors who have given their informed consent. The samples are then cataloged and stored in specialized conditions to preserve their quality and integrity.
Biobanks play a critical role in advancing medical research by providing researchers with access to large numbers of well-characterized biological samples. This allows them to study the underlying causes of diseases, develop new diagnostic tests and treatments, and evaluate the safety and effectiveness of drugs and other therapies. Biobanks may be established for specific research projects or as part of larger, more comprehensive efforts to build biomedical research infrastructure.
It is important to note that the use of biological specimens in research is subject to strict ethical guidelines and regulations, which are designed to protect the privacy and interests of donors and ensure that the samples are used responsibly and for legitimate scientific purposes.
A "periodical" in the context of medicine typically refers to a type of publication that is issued regularly, such as on a monthly or quarterly basis. These publications include peer-reviewed journals, magazines, and newsletters that focus on medical research, education, and practice. They may contain original research articles, review articles, case reports, editorials, letters to the editor, and other types of content related to medical science and clinical practice.
As a "Topic," periodicals in medicine encompass various aspects such as their role in disseminating new knowledge, their impact on clinical decision-making, their quality control measures, and their ethical considerations. Medical periodicals serve as a crucial resource for healthcare professionals, researchers, students, and other stakeholders to stay updated on the latest developments in their field and to share their findings with others.
A Tissue Bank is a specialized facility that collects, stores, and distributes human tissues for medical research, transplantation, or therapeutic purposes. These tissues can include organs, bones, skin, heart valves, tendons, and other bodily tissues that can be used for various medical applications.
Tissue banks follow strict regulations and guidelines to ensure the safety and quality of the tissues they handle. They implement rigorous screening and testing procedures to minimize the risk of disease transmission and maintain the integrity of the tissues. The tissues are stored under specific conditions, such as temperature and humidity, to preserve their function and viability until they are needed for use.
Tissue banks play a critical role in advancing medical research and improving patient outcomes by providing researchers and clinicians with access to high-quality human tissues for study and transplantation.
Paraffin embedding is a process in histology (the study of the microscopic structure of tissues) where tissue samples are impregnated with paraffin wax to create a solid, stable block. This allows for thin, uniform sections of the tissue to be cut and mounted on slides for further examination under a microscope.
The process involves fixing the tissue sample with a chemical fixative to preserve its structure, dehydrating it through a series of increasing concentrations of alcohol, clearing it in a solvent such as xylene to remove the alcohol, and then impregnating it with melted paraffin wax. The tissue is then cooled and hardened into a block, which can be stored, transported, and sectioned as needed.
Paraffin embedding is a commonly used technique in histology due to its relative simplicity, low cost, and ability to produce high-quality sections for microscopic examination.
Formaldehyde is a colorless, pungent, and volatile chemical compound with the formula CH2O. It is a naturally occurring substance that is found in certain fruits like apples and vegetables, as well as in animals. However, the majority of formaldehyde used in industry is synthetically produced.
In the medical field, formaldehyde is commonly used as a preservative for biological specimens such as organs, tissues, and cells. It works by killing bacteria and inhibiting the decaying process. Formaldehyde is also used in the production of various industrial products, including adhesives, resins, textiles, and paper products.
However, formaldehyde can be harmful to human health if inhaled or ingested in large quantities. It can cause irritation to the eyes, nose, throat, and skin, and prolonged exposure has been linked to respiratory problems and cancer. Therefore, it is essential to handle formaldehyde with care and use appropriate safety measures when working with this chemical compound.
"Access to information," in a medical context, refers to the ability of individuals, patients, healthcare providers, and researchers to obtain, request, and disseminate health-related data, records, research findings, and other important information. This includes access to personal medical records, clinical trial results, evidence-based practices, and public health statistics.
Promoting access to information is crucial for informed decision-making, ensuring transparency, advancing medical research, improving patient care, and enhancing overall healthcare system performance. Various laws, regulations, and policies at the local, national, and international levels aim to protect and facilitate access to information while balancing privacy concerns, data security, and intellectual property rights.
I'm sorry for any confusion, but "publishing" is not a term that has a medical definition. Publishing typically refers to the process of preparing and disseminating information, such as books, journals, or articles, to the public or a specific audience. It could involve both print and digital media. If you have any questions related to medicine or healthcare, I'd be happy to try to help answer those!
I'm sorry for any confusion, but "Internet" is a term that pertains to the global network of interconnected computers and servers that enable the transmission and reception of data via the internet protocol (IP). It is not a medical term and does not have a specific medical definition. If you have any questions related to medicine or health, I'd be happy to try to help answer them for you!
Medical libraries are collections of resources that provide access to information related to the medical and healthcare fields. They serve as a vital tool for medical professionals, students, researchers, and patients seeking reliable and accurate health information. Medical libraries can be physical buildings or digital platforms that contain various types of materials, including:
1. Books: Medical textbooks, reference books, and monographs that cover various topics related to medicine, anatomy, physiology, pharmacology, pathology, and clinical specialties.
2. Journals: Print and electronic peer-reviewed journals that publish the latest research findings, clinical trials, and evidence-based practices in medicine.
3. Databases: Online resources that allow users to search for and access information on specific topics, such as PubMed, MEDLINE, CINAHL, and Cochrane Library.
4. Multimedia resources: Audio and video materials, such as lectures, webinars, podcasts, and instructional videos, that provide visual and auditory learning experiences.
5. Electronic resources: E-books, databases, and other digital materials that can be accessed remotely through computers, tablets, or smartphones.
6. Patient education materials: Brochures, pamphlets, and other resources that help patients understand their health conditions, treatments, and self-care strategies.
7. Archives and special collections: Rare books, historical documents, manuscripts, and artifacts related to the history of medicine and healthcare.
Medical libraries may be found in hospitals, medical schools, research institutions, and other healthcare settings. They are staffed by trained librarians and information specialists who provide assistance with locating, accessing, and evaluating information resources. Medical libraries play a critical role in supporting evidence-based medicine, continuing education, and patient care.
A Database Management System (DBMS) is a software application that enables users to define, create, maintain, and manipulate databases. It provides a structured way to organize, store, retrieve, and manage data in a digital format. The DBMS serves as an interface between the database and the applications or users that access it, allowing for standardized interactions and data access methods. Common functions of a DBMS include data definition, data manipulation, data security, data recovery, and concurrent data access control. Examples of DBMS include MySQL, Oracle, Microsoft SQL Server, and MongoDB.
Computer communication networks (CCN) refer to the interconnected systems or groups of computers that are able to communicate and share resources and information with each other. These networks may be composed of multiple interconnected devices, including computers, servers, switches, routers, and other hardware components. The connections between these devices can be established through various types of media, such as wired Ethernet cables or wireless Wi-Fi signals.
CCNs enable the sharing of data, applications, and services among users and devices, and they are essential for supporting modern digital communication and collaboration. Some common examples of CCNs include local area networks (LANs), wide area networks (WANs), and the Internet. These networks can be designed and implemented in various topologies, such as star, ring, bus, mesh, and tree configurations, to meet the specific needs and requirements of different organizations and applications.
'Information Storage and Retrieval' in the context of medical informatics refers to the processes and systems used for the recording, storing, organizing, protecting, and retrieving electronic health information (e.g., patient records, clinical data, medical images) for various purposes such as diagnosis, treatment planning, research, and education. This may involve the use of electronic health record (EHR) systems, databases, data warehouses, and other digital technologies that enable healthcare providers to access and share accurate, up-to-date, and relevant information about a patient's health status, medical history, and care plan. The goal is to improve the quality, safety, efficiency, and coordination of healthcare delivery by providing timely and evidence-based information to support clinical decision-making and patient engagement.
A Tobacco Industry is a commercial sector involved in the cultivation, production, manufacturing, marketing, and distribution of tobacco and tobacco-related products. This can include growers who produce tobacco leaves, manufacturers who process the leaves into various forms (such as cigarettes, chewing tobacco, or snuff), and companies that market and distribute these products to consumers. It is important to note that the tobacco industry has been associated with significant health risks, as the use of tobacco products can lead to a range of serious health problems, including cancer, heart disease, and lung disease.
A factual database in the medical context is a collection of organized and structured data that contains verified and accurate information related to medicine, healthcare, or health sciences. These databases serve as reliable resources for various stakeholders, including healthcare professionals, researchers, students, and patients, to access evidence-based information for making informed decisions and enhancing knowledge.
Examples of factual medical databases include:
1. PubMed: A comprehensive database of biomedical literature maintained by the US National Library of Medicine (NLM). It contains citations and abstracts from life sciences journals, books, and conference proceedings.
2. MEDLINE: A subset of PubMed, MEDLINE focuses on high-quality, peer-reviewed articles related to biomedicine and health. It is the primary component of the NLM's database and serves as a critical resource for healthcare professionals and researchers worldwide.
3. Cochrane Library: A collection of systematic reviews and meta-analyses focused on evidence-based medicine. The library aims to provide unbiased, high-quality information to support clinical decision-making and improve patient outcomes.
4. OVID: A platform that offers access to various medical and healthcare databases, including MEDLINE, Embase, and PsycINFO. It facilitates the search and retrieval of relevant literature for researchers, clinicians, and students.
5. ClinicalTrials.gov: A registry and results database of publicly and privately supported clinical studies conducted around the world. The platform aims to increase transparency and accessibility of clinical trial data for healthcare professionals, researchers, and patients.
6. UpToDate: An evidence-based, physician-authored clinical decision support resource that provides information on diagnosis, treatment, and prevention of medical conditions. It serves as a point-of-care tool for healthcare professionals to make informed decisions and improve patient care.
7. TRIP Database: A search engine designed to facilitate evidence-based medicine by providing quick access to high-quality resources, including systematic reviews, clinical guidelines, and practice recommendations.
8. National Guideline Clearinghouse (NGC): A database of evidence-based clinical practice guidelines and related documents developed through a rigorous review process. The NGC aims to provide clinicians, healthcare providers, and policymakers with reliable guidance for patient care.
9. DrugBank: A comprehensive, freely accessible online database containing detailed information about drugs, their mechanisms, interactions, and targets. It serves as a valuable resource for researchers, healthcare professionals, and students in the field of pharmacology and drug discovery.
10. Genetic Testing Registry (GTR): A database that provides centralized information about genetic tests, test developers, laboratories offering tests, and clinical validity and utility of genetic tests. It serves as a resource for healthcare professionals, researchers, and patients to make informed decisions regarding genetic testing.
A User-Computer Interface (also known as Human-Computer Interaction) refers to the point at which a person (user) interacts with a computer system. This can include both hardware and software components, such as keyboards, mice, touchscreens, and graphical user interfaces (GUIs). The design of the user-computer interface is crucial in determining the usability and accessibility of a computer system for the user. A well-designed interface should be intuitive, efficient, and easy to use, minimizing the cognitive load on the user and allowing them to effectively accomplish their tasks.
Retrospective studies, also known as retrospective research or looking back studies, are a type of observational study that examines data from the past to draw conclusions about possible causal relationships between risk factors and outcomes. In these studies, researchers analyze existing records, medical charts, or previously collected data to test a hypothesis or answer a specific research question.
Retrospective studies can be useful for generating hypotheses and identifying trends, but they have limitations compared to prospective studies, which follow participants forward in time from exposure to outcome. Retrospective studies are subject to biases such as recall bias, selection bias, and information bias, which can affect the validity of the results. Therefore, retrospective studies should be interpreted with caution and used primarily to generate hypotheses for further testing in prospective studies.
A nucleic acid database is a type of biological database that contains sequence, structure, and functional information about nucleic acids, such as DNA and RNA. These databases are used in various fields of biology, including genomics, molecular biology, and bioinformatics, to store, search, and analyze nucleic acid data.
Some common types of nucleic acid databases include:
1. Nucleotide sequence databases: These databases contain the primary nucleotide sequences of DNA and RNA molecules from various organisms. Examples include GenBank, EMBL-Bank, and DDBJ.
2. Structure databases: These databases contain three-dimensional structures of nucleic acids determined by experimental methods such as X-ray crystallography or nuclear magnetic resonance (NMR) spectroscopy. Examples include the Protein Data Bank (PDB) and the Nucleic Acid Database (NDB).
3. Functional databases: These databases contain information about the functions of nucleic acids, such as their roles in gene regulation, transcription, and translation. Examples include the Gene Ontology (GO) database and the RegulonDB.
4. Genome databases: These databases contain genomic data for various organisms, including whole-genome sequences, gene annotations, and genetic variations. Examples include the Human Genome Database (HGD) and the Ensembl Genome Browser.
5. Comparative databases: These databases allow for the comparison of nucleic acid sequences or structures across different species or conditions. Examples include the Comparative RNA Web (CRW) Site and the Sequence Alignment and Modeling (SAM) system.
Nucleic acid databases are essential resources for researchers to study the structure, function, and evolution of nucleic acids, as well as to develop new tools and methods for analyzing and interpreting nucleic acid data.
Biomedical research is a branch of scientific research that involves the study of biological processes and diseases in order to develop new treatments and therapies. This type of research often involves the use of laboratory techniques, such as cell culture and genetic engineering, as well as clinical trials in humans. The goal of biomedical research is to advance our understanding of how living organisms function and to find ways to prevent and treat various medical conditions. It encompasses a wide range of disciplines, including molecular biology, genetics, immunology, pharmacology, and neuroscience, among others. Ultimately, the aim of biomedical research is to improve human health and well-being.
A genetic database is a type of biomedical or health informatics database that stores and organizes genetic data, such as DNA sequences, gene maps, genotypes, haplotypes, and phenotype information. These databases can be used for various purposes, including research, clinical diagnosis, and personalized medicine.
There are different types of genetic databases, including:
1. Genomic databases: These databases store whole genome sequences, gene expression data, and other genomic information. Examples include the National Center for Biotechnology Information's (NCBI) GenBank, the European Nucleotide Archive (ENA), and the DNA Data Bank of Japan (DDBJ).
2. Gene databases: These databases contain information about specific genes, including their location, function, regulation, and evolution. Examples include the Online Mendelian Inheritance in Man (OMIM) database, the Universal Protein Resource (UniProt), and the Gene Ontology (GO) database.
3. Variant databases: These databases store information about genetic variants, such as single nucleotide polymorphisms (SNPs), insertions/deletions (INDELs), and copy number variations (CNVs). Examples include the Database of Single Nucleotide Polymorphisms (dbSNP), the Catalogue of Somatic Mutations in Cancer (COSMIC), and the International HapMap Project.
4. Clinical databases: These databases contain genetic and clinical information about patients, such as their genotype, phenotype, family history, and response to treatments. Examples include the ClinVar database, the Pharmacogenomics Knowledgebase (PharmGKB), and the Genetic Testing Registry (GTR).
5. Population databases: These databases store genetic information about different populations, including their ancestry, demographics, and genetic diversity. Examples include the 1000 Genomes Project, the Human Genome Diversity Project (HGDP), and the Allele Frequency Net Database (AFND).
Genetic databases can be publicly accessible or restricted to authorized users, depending on their purpose and content. They play a crucial role in advancing our understanding of genetics and genomics, as well as improving healthcare and personalized medicine.
I am not aware of a widely accepted medical definition for the term "software," as it is more commonly used in the context of computer science and technology. Software refers to programs, data, and instructions that are used by computers to perform various tasks. It does not have direct relevance to medical fields such as anatomy, physiology, or clinical practice. If you have any questions related to medicine or healthcare, I would be happy to try to help with those instead!
I'm sorry for any confusion, but "Italy" is not a medical term or concept. It is a country located in Southern Europe. If you have any questions related to medical terminology or health-related topics, I would be happy to try and help answer those for you.