Browse 8,700 peer-reviewed studies on electromagnetic field health effects from 4 research libraries.
Showing 675 studies in Reproductive Health
Joan Arehart-Treichel · 1974
This 1974 research explored electronic devices using heat and ultrasound as potential male contraceptive methods, examining their effectiveness and safety for temporarily reducing fertility. The study investigated whether electromagnetic technologies could provide a reversible alternative to permanent surgical procedures or hormonal approaches.
Jose Daels, MD · 1973
This 1973 study investigated using microwave energy to heat the uterine wall during childbirth, examining its potential as pain relief during labor. The research explored whether controlled microwave heating could provide analgesic effects for women in parturition. This represents early medical application research of microwave technology in obstetric care.
Department of the Navy Electronic Systems Command · 1973
The U.S. Navy's 1973 Sanguine program conducted comprehensive research to assess whether extremely low frequency (ELF) electromagnetic radiation from a proposed military communications system would harm biological and ecological systems. The study examined effects across multiple areas including genetics, fertility, plant growth, animal behavior, and bird migration patterns. This represents one of the earliest large-scale government investigations into ELF health effects.
A. ZERVINS, D.V.M. · 1973
Researchers exposed 62 chick eggs to a 26-kHz electromagnetic field for 19 days to study effects on embryo development. While exposed eggs had a lower hatching rate (64.5%) compared to controls (86.5%), the difference wasn't statistically significant. The study found no conclusive evidence that this specific EMF frequency disrupts chick embryo development.
Jose Daels, MD · 1973
This 1973 research examined microwave heating effects on the uterine wall during childbirth, investigating how electromagnetic energy might affect this critical reproductive process. The study explored the relationship between microwave exposure and uterine tissue heating during labor and delivery. This represents early research into how EMF exposure might impact pregnancy and birth outcomes.
W. Ludwig, M. A. Persinger, K.-P. Ossenkopp · 1973
This 1973 study exposed pregnant rats and their offspring to extremely low frequency (ELF) rotating magnetic fields, finding significant changes in behavior and organ weights including thyroid and testicles. The research suggests ELF fields can influence nervous system development during critical prenatal and early life periods.
Dietzel F, Kern W, Steckenmesser R · 1972
Researchers exposed 749 pregnant rats to short-wave radiofrequency therapy during early pregnancy, causing body temperatures to reach 42°C (108°F). The heat exposure resulted in numerous birth defects and embryo deaths, with the type of malformation depending on when during pregnancy the exposure occurred.
FRANZ DIETZEL, WALTER KERN, RAINER STECKENMESSER · 1972
This 1972 German study exposed 749 pregnant rats to shortwave radiofrequency radiation during early pregnancy, heating their body temperature to 42°C (107.6°F). The researchers found widespread birth defects and fetal death, with the type of malformation depending on which stage of pregnancy the exposure occurred.
Harte, C · 1972
Researchers exposed evening primrose pollen to radio waves (1.5 meter wavelength) for 4 and 12 hours, then used this pollen to fertilize normal flowers. The resulting plants showed multiple signs of genetic damage including sterility, chromosomal abnormalities, and lethal mutations across three generations.
FRANZ DIETZEL, WALTER KERN, RAINER STECKENMESSER · 1972
German researchers exposed 749 pregnant rats to shortwave radiation therapy during early pregnancy, heating their body temperatures to 42°C (107.6°F). The treatment caused widespread birth defects and fetal death, with the type of malformation directly linked to which developmental stage the exposure occurred. This 1972 study demonstrates how radiofrequency radiation can severely disrupt fetal development through heating effects.
Wilbert Shimoda · 1971
This 1971 thesis proposal examined how microwave radiation and heat exposure could damage reproductive organs in male dogs. The research focused on testicular tissue, which is particularly vulnerable to both thermal and electromagnetic effects. This early work helped establish that microwave radiation could cause biological damage beyond simple heating effects.
Joseph C. Sharp, Carl J. Paperiello · 1971
Researchers exposed female rats to 2450 MHz microwave radiation (the same frequency as microwave ovens) and measured how it affected cell division in various organs. Higher power levels (32 mW/cm2) reduced cell division in ovaries and intestines, while lower levels (16 mW/cm2) actually increased it in ovaries. This suggests microwave exposure can disrupt normal cellular processes in reproductive and digestive tissues.
S. M Michaelson · 1971
This 1971 government review examined microwave radiation's biological effects on animals, finding that exposure at 100 mW/cm² or higher causes tissue heating that can damage organs with poor blood circulation. The study identified the eye lens and testes as particularly vulnerable to microwave-induced thermal damage due to their limited ability to dissipate heat.
S. M Michaelson · 1971
This 1971 government review examined biological effects of microwave radiation on animals to help establish safety standards. The study found that microwave exposure primarily causes heating effects, with organs like the eyes and testes being most vulnerable to damage due to poor blood circulation. At exposure levels of 100 mW/cm² or higher, animals showed three phases of thermal response that could lead to reversible or permanent tissue damage.
J. B. MULDER · 1971
This 1971 review examined how electromagnetic energy waves, including visible and invisible light, affect animal behavior patterns. Researchers found that various forms of electromagnetic exposure altered reproductive ability, offspring sex ratios, activity levels, and lifespan in animals. However, studies showed widely inconsistent results even under seemingly similar conditions, highlighting the need for better controlled research.
Mohammed Moayer · 1971
This 1971 study examined how short-wave radiofrequency radiation affects the structure and appearance of placental tissue in laboratory animals. The research focused on identifying physical changes to the placenta following RF exposure during pregnancy. While specific findings aren't available, this represents early research into how electromagnetic fields might impact developing pregnancies.
Mohammed Moayer · 1971
This 1971 study examined how short-wave radiofrequency radiation affected the physical structure of placentas in laboratory rats. The research focused on documenting morphological (structural) changes in placental tissue following RF exposure. This early investigation helped establish a foundation for understanding how electromagnetic fields might impact pregnancy outcomes.
Charles C. Conley · 1970
This 1970 review examined the first studies of how extremely weak magnetic fields (weaker than Earth's natural field) affect living organisms. Researchers found that plants, simple animals, and even mice showed changes in growth, reproduction, aging, and cellular functions when exposed to these nearly absent magnetic fields.
Charles C. Conley · 1970
This 1970 review examined the first decade of research on how magnetic fields weaker than Earth's natural field affect living organisms. Scientists found that invertebrates, single-celled organisms, and plants showed measurable changes in growth, reproduction, aging, and behavior when exposed to very low or nearly zero magnetic fields.
Thomas A. Knutson · 1969
Researchers exposed developing quail embryos to magnetic fields during incubation and found accelerated growth of somites (early spine structures). Twenty percent of embryos showed reversed body torsion, with non-uniform magnetic fields proving more disruptive than uniform ones. This early study demonstrates that electromagnetic fields can alter fundamental developmental processes in vertebrate embryos.
D. E. JANES et al. · 1969
This 1969 study examined how 2450 MHz microwave radiation affects Chinese hamsters, finding significant biological damage across multiple organ systems. Researchers documented eye lens clouding, reproductive system damage including testicular degeneration and reduced sperm production, and chromosome irregularities during cell division. The study also found protein changes at the cellular level, suggesting microwave radiation disrupts fundamental biological processes.
D. E. JANES et al. · 1969
This 1969 study exposed Chinese hamsters to 2450 MHz microwave radiation (the same frequency used in microwave ovens) and found it reduced protein production in liver and testis tissues while causing chromosome abnormalities in bone marrow cells. The research demonstrated that microwave radiation can interfere with basic cellular functions including protein synthesis and genetic material integrity.
M. A. K. Hamid et al. · 1969
This 1969 study exposed chickens to continuous microwave radiation and found no harmful effects on growth, egg production, fertility, or survival. The researchers actually observed potential beneficial effects, though they noted this was preliminary data requiring further investigation.
John S. Krebs · 1968
This 1968 study exposed male mice to X-ray and neutron radiation to understand how ionizing radiation damages reproductive tissue. Researchers found that testicular tissue loss followed a predictable pattern, with neutrons being nearly 4 times more damaging than X-rays, and identified that germinal cells (sperm-producing cells) were the primary target of radiation damage.
Krebs JS · 1968
This 1968 technical report examined how radiation exposure damages male reproductive organs by studying the survival of stem cells in animal testes. The research analyzed the relationship between radiation-induced weight loss in testes and the underlying damage to stem cells responsible for sperm production. This foundational work helped establish how radiation affects reproductive health at the cellular level.