Radiation, Nonionizing
Internet
Leukocytes
Occupational Exposure
Radioactive Hazard Release
Terrorism
Disaster Planning
Mass Casualty Incidents
September 11 Terrorist Attacks
Terminology as Topic
Radiofrequency electrocution (196 MHz). (1/38)
Radiofrequency (RF) electrocutions are uncommon. A case of electrocution at 196 MHz is presented partly because there are no previous reports with frequencies as high as this, and partly to assist in safety standard setting. A 53-year-old technician received two brief exposures to both hands of 2A current at 196 MHz. He did not experience shock or burn. Progressively over the next days and months he developed joint pains in the hands, wrists and elbows, altered temperature and touch sensation and parasthesiae. Extensive investigation found no frank neurological abnormality, but there were changes in temperature perception in the palms and a difference in temperature between hands. His symptoms were partly alleviated with ultra-sound therapy, phenoxybenzamine and glyceryl trinitrate patches locally applied, but after several months he continues to have some symptoms. The biophysics and clinical aspects are discussed. It is postulated that there was mainly surface flow of current and the micro-vasculature was effected. Differences to 50 Hz electrocution are noted. Electrocution at 196 MHz, even in the absence of burns may cause long-term morbidity to which physicians should be alerted. Safety standards should consider protection from electrocution at these frequencies. (+info)Interspecific variability in sensitivity to UV radiation and subsequent recovery in selected isolates of marine bacteria. (2/38)
The interspecific variability in the sensitivity of marine bacterial isolates to UV-B (295- to 320-nm) radiation and their ability to recover from previous UV-B stress were examined. Isolates originating from different microenvironments of the northern Adriatic Sea were transferred to aged seawater and exposed to artificial UV-B radiation for 4 h and subsequently to different radiation regimens excluding UV-B to determine the recovery from UV-B stress. Bacterial activity was assessed by thymidine and leucine incorporation measurements prior to and immediately after the exposure to UV-B and after the subsequent exposure to the different radiation regimens. Large interspecific differences among the 11 bacterial isolates were found in the sensitivity to UV-B, ranging from 21 to 92% inhibition of leucine incorporation compared to the bacterial activity measured in dark controls and from 14 to 84% for thymidine incorporation. Interspecific differences in the recovery from the UV stress were also large. An inverse relation was detectable between the ability to recover under dark conditions and the recovery under photosynthetic active radiation (400 to 700 nm). The observed large interspecific differences in the sensitivity to UV-B radiation and even more so in the subsequent recovery from UV-B stress are not related to the prevailing radiation conditions of the microhabitats from which the bacterial isolates originate. Based on our investigations on the 11 marine isolates, we conclude that there are large interspecific differences in the sensitivity to UV-B radiation and even larger differences in the mechanisms of recovery from previous UV stress. This might lead to UV-mediated shifts in the bacterioplankton community composition in marine surface waters. (+info)Human brain activity during exposure to radiofrequency fields emitted by cellular phones. (3/38)
OBJECTIVES: The aim of this study was to explore the possible influence of radiofrequency (RF) radiation exposure on human brain function. METHODS: The electroencephalographic (EEG) activity of 19 volunteers was quantitatively analyzed. Ten of the subjects were men (28-48 years of age) and 9 were women (32-57 years of age). The sources of exposure were 5 different cellular phones (analogue and digital models) operating at a frequency of 900 MHz or 1800 MHz. The EEG activity was recorded in an awake, closed-eyes situation. Six 30-minute experiments, including 1 sham exposure, were made for each subject. The duration of a real exposure phase was 20 minutes. RESULTS: Exposure to one of the phones caused a statistically significant change in the absolute power at the delta band of the EEG recording. However, no difference was seen in the relative power of the same band, and no changes occurred during exposure to other phones at any frequency bands. CONCLUSIONS: The findings of this study suggest that exposure to radiofrequency fields emitted by cellular phones has no abnormal effects on human EEG activity. The observed difference in 1 parameter was probably caused by statistical chance. (+info)The data sources which may help strengthen the epidemiological evidence for the hormonal hypothesis of sex determination in man. (4/38)
The hypothesis that parental hormone levels around the time of conception partially control offspring sex ratios-though here taken to be true in substance-will need a great deal of work to specify with any accuracy. We do not know with any certainty which hormones are involved, nor how they are implicated. Answers to these two questions are only likely to emerge after prolonged experimental work. And it is fair to say that that work has not yet started. I assume that experimental workers will not embark on such a project until it is perfectly clear that there is a watertight case that mammalian parental hormone levels somehow influence offspring sex ratios. The present note indicates where further (human) evidence for that case will be found. In regard to human beings, much of the required information is held by clinics and registries not primarily concerned with reproductive biology. This point is illustrated here in regard to toxicology, teratology, radiation medicine, neurology, psychiatry, oncology, dermatology, rheumatology, occupational medicine and sports medicine as well as obstetrics and gynaecology. Tests (based on the hypothesis) are offered for intrauterine endocrine causes of malformations, and for pre- and post-natal endocrine causes of disease. (+info)Low-energy extracorporeal shock-wave treatment (ESWT) for tendinitis of the supraspinatus. A prospective, randomised study. (5/38)
We have performed a controlled, randomised study to analyse the effects of low-energy shock-wave therapy (ESWT) on function and pain in tendinitis of the supraspinatus without calcification. There were 20 patients in the treatment group and 20 in the control group. The former group received 6,000 impulses (energy flux density, 0.11 mJ/mm2) in three sessions after local anaesthesia. The control group had 6000 impulses of sham ESWT after local anaesthesia. The patients were examined at six and 12 weeks after treatment by an independent observer who evaluated the Constant score and level of pain. We found an increase in function and a reduction of pain in both groups (p < or = 0.001). Statistical analysis showed no difference between the groups for the Constant score and for pain. We therefore do not recommend ESWT for the treatment of tendinitis of supraspinatus. (+info)Extremely low frequency electromagnetic fields (EMF) and brain cancer in adults and children: review and comment. (6/38)
Epidemiologic and experimental research on the potential carcinogenic effects of extremely low frequency electromagnetic fields (EMF) has now been conducted for over two decades. Cancer epidemiology studies in relation to EMF have focused primarily on brain cancer and leukemia, both from residential sources of exposure in children and adults and from occupational exposure in adult men. Because genotoxic effects of EMF have not been shown, most recent laboratory research has attempted to show biological effects that could be related to cancer promotion. In this report, we briefly review residential and occupational EMF studies on brain cancer. We also provide a general review of experimental studies as they relate both to the biological plausibility of an EMF-brain cancer relation and to the insufficiency of such research to help guide exposure assessment in epidemiologic studies. We conclude from our review that no recent research, either epidemiologic or experimental, has emerged to provide reasonable support for a causal role of EMF on brain cancer. (+info)Safety assessment of near infrared light emitting diodes for diffuse optical measurements. (7/38)
BACKGROUND: Near infrared (NIR) light has been used widely to monitor important hemodynamic parameters in tissue non-invasively. Pulse oximetry, near infrared spectroscopy, and diffuse optical tomography are examples of such NIR light-based applications. These and other similar applications employ either lasers or light emitting diodes (LED) as the source of the NIR light. Although the hazards of laser sources have been addressed in regulations, the risk of LED sources in such applications is still unknown. METHODS: Temperature increase of the human skin caused by near infrared LED has been measured by means of in-vivo and in-vitro experiments. Effects of the conducted and radiated heat in the temperature increase have been analyzed separately. RESULTS: Elevations in skin temperature up to 10 degrees C have been observed. The effect of radiated heat due to NIR absorption is low--less than 0.5 degrees C--since emitted light power is comparable to the NIR part of sunlight. The conducted heat due to semiconductor junction of the LED can cause temperature increases up to 9 degrees C. It has been shown that adjusting operational parameters by amplitude modulating or time multiplexing the LED decreases the temperature increase of the skin significantly. CONCLUSION: In this study, we demonstrate that the major risk source of the LED in direct contact with skin is the conducted heat of the LED semiconductor junction, which may cause serious skin burns. Adjusting operational parameters by amplitude modulating or time multiplexing the LED can keep the LED within safe temperature ranges. (+info)Magnetic field effects on pineal indoleamine metabolism and possible biological consequences. (8/38)
In recent years, there has been a great deal of publicity concerning the possible health effects of electric and/or magnetic field exposure. One of the most frequently reported observations after the exposure of animals to either electric or magnetic fields relates to alterations in the metabolism of serotonin (5HT) to melatonin within the pineal gland. This review summarizes these results particularly in animals exposed to intermittently inverted, non-time varying magnetic fields, i.e., pulsed static magnetic fields. When exposure occurs at night, the conversation of 5HT to melatonin is typically depressed, not unlike that after light exposure at night. The mechanisms by which pulsed magnetic fields alter the ability of the pineal to convert 5HT to the chief pineal hormone melatonin remains unknown but may involve effects on any or all of the following: the retinas, the suprachiasmatic nuclei, the peripheral sympathetic nervous system, and the pinealocytes. Results to date suggest that induced electrical currents (eddy currents) produced by the pulsed magnetic fields are particularly detrimental to pineal indoleamine metabolism and may be an important causative factor in the metabolic changes measured. The physiological consequences of perturbations in the melatonin rhythm induced by magnetic field exposure remain unknown. (+info)Nonionizing radiation refers to the type of radiation that does not have sufficient energy to cause ionization in atoms or molecules. Ionization is the process where electrons are knocked out of an atom, creating ions. Nonionizing radiation includes lower-energy forms of radiation such as radio waves, microwaves, infrared and visible light, ultraviolet (UV) light, and some higher-energy portions of the electromagnetic spectrum such as X-rays and gamma rays with energies below 10 keV (kiloelectron volts).
While nonionizing radiation does not have enough energy to ionize atoms, it can still cause excitation of atoms and molecules, leading to various effects such as heating, vibrational energy transfer, or chemical reactions. Some forms of nonionizing radiation, particularly UV light, can also cause damage to living tissue, including sunburn and skin cancer. However, nonionizing radiation does not have the same potential for causing direct damage to DNA and other cellular structures as ionizing radiation, which is associated with higher risks of cancer and other health effects at similar exposure levels.
Electromagnetic fields (EMFs) are invisible forces that result from the interaction between electrically charged objects. They are created by natural phenomena, such as the Earth's magnetic field, as well as by human-made sources, such as power lines, electrical appliances, and wireless communication devices.
EMFs are characterized by their frequency and strength, which determine their potential biological effects. Low-frequency EMFs, such as those produced by power lines and household appliances, have frequencies in the range of 0 to 300 Hz. High-frequency EMFs, such as those produced by wireless communication devices like cell phones and Wi-Fi routers, have frequencies in the range of 100 kHz to 300 GHz.
Exposure to EMFs has been linked to a variety of health effects, including increased risk of cancer, reproductive problems, neurological disorders, and oxidative stress. However, more research is needed to fully understand the potential health risks associated with exposure to EMFs and to establish safe exposure limits.
I'm sorry for any confusion, but "Magnetic Fields" is not a term typically used in medical definitions. It is a concept from physics that describes the region around a magnetic material or a moving electric charge where its magnetic influence can be felt.
However, if you're referring to "Magnetic Resonance Imaging (MRI)," it's a common medical imaging technique that uses magnetic fields and radio waves to create detailed images of the organs and tissues within the body. In this context, a strong magnetic field is used to align the spins of certain atoms in the body, and then radio waves are used to knock these atoms out of alignment and measure the energy they release as they realign. This information is used to create detailed images that can help diagnose a variety of medical conditions.
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!
Leukocytes, also known as white blood cells (WBCs), are a crucial component of the human immune system. They are responsible for protecting the body against infections and foreign substances. Leukocytes are produced in the bone marrow and circulate throughout the body in the bloodstream and lymphatic system.
There are several types of leukocytes, including:
1. Neutrophils - These are the most abundant type of leukocyte and are primarily responsible for fighting bacterial infections. They contain enzymes that can destroy bacteria.
2. Lymphocytes - These are responsible for producing antibodies and destroying virus-infected cells, as well as cancer cells. There are two main types of lymphocytes: B-lymphocytes and T-lymphocytes.
3. Monocytes - These are the largest type of leukocyte and help to break down and remove dead or damaged tissues, as well as microorganisms.
4. Eosinophils - These play a role in fighting parasitic infections and are also involved in allergic reactions and inflammation.
5. Basophils - These release histamine and other chemicals that cause inflammation in response to allergens or irritants.
An abnormal increase or decrease in the number of leukocytes can indicate an underlying medical condition, such as an infection, inflammation, or a blood disorder.
I'm sorry for any confusion, but "magnetics" is not a term that is commonly used in medical definitions. It is a term more frequently used in physics and engineering to refer to things related to magnets or magnetic fields. If you have any questions about medical terminology or concepts, I would be happy to try to help with those!
Occupational exposure refers to the contact of an individual with potentially harmful chemical, physical, or biological agents as a result of their job or occupation. This can include exposure to hazardous substances such as chemicals, heavy metals, or dusts; physical agents such as noise, radiation, or ergonomic stressors; and biological agents such as viruses, bacteria, or fungi.
Occupational exposure can occur through various routes, including inhalation, skin contact, ingestion, or injection. Prolonged or repeated exposure to these hazards can increase the risk of developing acute or chronic health conditions, such as respiratory diseases, skin disorders, neurological damage, or cancer.
Employers have a legal and ethical responsibility to minimize occupational exposures through the implementation of appropriate control measures, including engineering controls, administrative controls, personal protective equipment, and training programs. Regular monitoring and surveillance of workers' health can also help identify and prevent potential health hazards in the workplace.
A "Radioactive Hazard Release" is defined in medical and environmental health terms as an uncontrolled or accidental release of radioactive material into the environment, which can pose significant risks to human health and the ecosystem. This can occur due to various reasons such as nuclear accidents, improper handling or disposal of radioactive sources, or failure of radiation-generating equipment.
The released radioactive materials can contaminate air, water, and soil, leading to both external and internal exposure pathways. External exposure occurs through direct contact with the skin or by inhaling radioactive particles, while internal exposure happens when radioactive substances are ingested or inhaled and become deposited within the body.
The health effects of radioactive hazard release depend on several factors, including the type and amount of radiation released, the duration and intensity of exposure, and the sensitivity of the exposed individuals. Potential health impacts range from mild radiation sickness to severe diseases such as cancer and genetic mutations, depending on the level and length of exposure.
Prompt identification, assessment, and management of radioactive hazard releases are crucial to minimize potential health risks and protect public health.
I'm sorry for any confusion, but "terrorism" is not a term that has a specific medical definition. It is a concept that is typically defined within the contexts of criminal law, international relations, and political science. Generally, terrorism refers to the use of violence or threat of violence, especially against civilians, in the pursuit of political, religious, or ideological objectives. If you have any questions related to medicine or health, I'd be happy to try to help answer those for you!
Disaster planning in a medical context refers to the process of creating and implementing a comprehensive plan for responding to emergencies or large-scale disasters that can impact healthcare facilities, services, and patient care. The goal of disaster planning is to minimize the impact of such events on the health and well-being of patients and communities, ensure continuity of medical services, and protect healthcare infrastructure and resources.
Disaster planning typically involves:
1. Risk assessment: Identifying potential hazards and assessing their likelihood and potential impact on healthcare facilities and services.
2. Developing a disaster plan: Creating a detailed plan that outlines the steps to be taken before, during, and after a disaster to ensure the safety of patients, staff, and visitors, as well as the continuity of medical care.
3. Training and education: Providing training and education to healthcare personnel on disaster preparedness, response, and recovery.
4. Exercises and drills: Conducting regular exercises and drills to test the effectiveness of the disaster plan and identify areas for improvement.
5. Resource management: Identifying and securing necessary resources, such as medical supplies, equipment, and personnel, to support disaster response efforts.
6. Communication and coordination: Establishing clear communication protocols and coordinating with local emergency responders, public health authorities, and other healthcare facilities to ensure a coordinated response to disasters.
7. Recovery and restoration: Developing plans for restoring medical services and infrastructure after a disaster has occurred.
Disaster planning is an essential component of healthcare delivery and is critical to ensuring the safety and well-being of patients and communities during emergencies or large-scale disasters.
A Mass Casualty Incident (MCI) is a situation in which the number of injured or deceased individuals exceeds the local resources available to respond and manage the incident. It typically involves multiple victims, often resulting from natural disasters, transportation accidents, terrorist attacks, or industrial incidents. The severity and scale of injuries require additional resources, coordination, and response from regional, national, or international emergency management and healthcare systems.
I'm sorry for any confusion, but "September 11 Terrorist Attacks" is a historical event rather than a medical condition or term. Therefore, it doesn't have a specific medical definition. However, I can provide some context:
The September 11 Terrorist Attacks, often referred to as 9/11, were a series of coordinated terrorist attacks that occurred in the United States on September 11, 2001. These attacks were carried out by the Islamic extremist group al-Qaeda. The attacks involved the hijacking of four commercial airplanes. Two of these planes were flown into the Twin Towers of the World Trade Center complex in New York City, causing both towers to collapse within hours. Another plane hit the Pentagon building in Arlington, Virginia, and the fourth crashed in a field in Pennsylvania after passengers attempted to overcome the hijackers.
The attacks resulted in thousands of deaths and injuries, making it one of the deadliest terrorist attacks in world history. The physical and psychological health effects were significant and far-reaching, affecting not only the survivors and first responders but also the nation as a whole. These effects included acute trauma reactions, post-traumatic stress disorder (PTSD), depression, anxiety, and various physical health issues.
While "September 11 Terrorist Attacks" is not a medical term, it is associated with numerous mental and physical health issues that have been studied and documented in the medical and psychological literature.
"Terminology as a topic" in the context of medical education and practice refers to the study and use of specialized language and terms within the field of medicine. This includes understanding the meaning, origins, and appropriate usage of medical terminology in order to effectively communicate among healthcare professionals and with patients. It may also involve studying the evolution and cultural significance of medical terminology. The importance of "terminology as a topic" lies in promoting clear and accurate communication, which is essential for providing safe and effective patient care.
Hazardous substances, in a medical context, refer to agents that pose a risk to the health of living organisms. These can include chemicals, biological agents (such as bacteria or viruses), and physical hazards (like radiation). Exposure to these substances can lead to a range of adverse health effects, from acute symptoms like irritation and poisoning to chronic conditions such as cancer, neurological disorders, or genetic mutations.
The classification and regulation of hazardous substances are often based on their potential for harm, the severity of the associated health risks, and the conditions under which they become dangerous. These assessments help inform safety measures, exposure limits, and handling procedures to minimize risks in occupational, environmental, and healthcare settings.