Project description:The biological effect of radiofrequency (RF) fields remains controversial. We address this issue by examining whether RF fields can cause changes in gene expression. We observed that 221 genes altered their expression after a 2-hour exposure. The number of affected genes increased to 759 after a 6-hour exposure. Functional classification of the affected genes reveals that apoptosis-related genes were among the up-regulated ones and the cell cycle genes among the down-regulated ones. We observed no significant increase in the expression of heat shock genes. These results indicate that the RF fields at 2.45 GHz can alter gene expression in cultured human cells through non-thermal mechanism. Keywords: gene expression SAGE We used the pulsed RF fields at a frequency of 2.45 GHz that is commonly used in telecommunication to expose cultured human HL-60 cells. We used the SAGE (serial analysis of gene expression) method to measure the RF effect on gene expression at the genome level.

Project description:The biological effect of radiofrequency (RF) fields remains controversial. We address this issue by examining whether RF fields can cause changes in gene expression. We observed that 221 genes altered their expression after a 2-hour exposure. The number of affected genes increased to 759 after a 6-hour exposure. Functional classification of the affected genes reveals that apoptosis-related genes were among the up-regulated ones and the cell cycle genes among the down-regulated ones. We observed no significant increase in the expression of heat shock genes. These results indicate that the RF fields at 2.45 GHz can alter gene expression in cultured human cells through non-thermal mechanism. Keywords: gene expression SAGE

Project description:This study investigates the effects of non-thermal levels of 900 MHz radiofrequency electromagnetic field (RF-EMF) which is used in mobile phone technology on neurodevelopment and neural stem cell differentiation. In vivo in the rat, the effects of pre- and post-natal 0.08 and 0.4 W/kg exposure were assessed on the proteomic profile at PND postnatal day 0 (PND) and on proliferation, synaptogenesis, and oxidative stress in the hippocampus and primary motor cortex of rats at PND 8 and PND 17. Complementary Mechanistic endpoints on cell differentiation were studied in vitro using stem cells exposed to 900 MHz RF-EMF at a non-thermal level for 3 or 7 days in vitro at the lowest SAR (0.08 W/kg). Our in vivo results showed a decrease in BDNF level and cells proliferation with a decrease in synapses balance. Increased proliferation, apoptosis, and double-strand DNA breaks in neural stem cells (NSCs) were also observed. Smaller ratio of B1 cells and a higher ratio of oligodendrocyte progenitor cells and astrocytes were observed in the exposed NSPCs. These findings suggest that developmental RF-EMF exposure induce changes in neurodevelopment in vivo from PND 0 and until PND 17 specifically on cellular proliferation supported by alterations in NSPCs in vitro, leading to the hypothesis of a vulnerability of developing central nervous system towards RF-EMF exposures at regulatory thresholds.

Project description:Neurodevelopmental disorders pose a severe health burden in our society, with remarkably increasing prevalence in children. Though radiofrequency radiation (RF) exposure to the prenatal brain is one of the environmental risks strongly associated with neurobehavioral disorders, its direct impact on human brain development remains largely unknown. Here we use human brain organoids representing the cortex, namely cortical organoids (hCOs) from human embryonic stem cells (hESC), to examine the effects of RF from mobile phones on corticogenesis. We found that RF exposure to brain organoids leads to structural impairment and the defective mitotic behaviors of radial glia progenitors, which carry out critical roles in neocortical expansion. We further uncovered that RF-treated organoids acquire the dysregulation in the transcriptional program, including the aberrant expression of autism risk genes and the morphologically and functionally abnormal neurons. Moreover, the RF shield made complete protection of the detrimental impact of RF on corticogenesis. Finally, we identified small molecule inhibitors for BET proteins that ameliorated RF-induced damages in cortical organoids. Our findings demonstrate how RF exposure impairs brain development and suggest new strategies to prevent RF-mediated brain damage.

Project description:HT-29 and SW620

Project description:The human brain represents one of the most complex organs in our body, with development regulated by an intricate genetic program. Recently, non-genetic factors, such as prenatal stress, infection, and diet, have been shown to influence brain development. Radiofrequency radiation (RF; 800-2,400 MHz), emitted by natural and artificial sources such as microwaves and cell phones, represents a non-invasive environmental factor. Using human cortical organoids (hCOs) derived from human embryonic stem cells (hESCs), we investigate RF's effects on corticogenesis. We find that RF exposure regulates the differentiation of human and non-human primate radial glia progenitors, maintaining stem cell identity and delaying differentiation. Neurons differentiated under RF treatment show induction of expression of human endogenous retroviruses. Importantly, inhibitors for the BET (bromodomain and extraterminal) protein rescue RF-induced developmental defects in hCOs. Our findings reveal a mechanism by which RF modulates early brain development, offering a non-biological approach to regulate neural stem cell self-renewal.

Project description:Despite many studies over a decade, it still remains ambiguous as to the real biological effects induced by radiofrequency electromagnetic fields (RF EMF). Epidemiological studies indicates that long-term exposure to EMF could increase the risk of breast cancer. Some reports have showed that in vitro EMF exposures change cellular gene expression. In this study, we investigated global gene expression responses to RF EMF simulating the Global System for Mobile Communications (GSM) 1800 MHz signal in human breast cancer cell line MCF-7 using transcriptomic approaches. MCF-7 cells were intermittently (5 min fields on/10 min fields off) exposed to RF EMF at an average specific absorption rate (SAR) of 2.0 W/kg (2 W/kg exposure group) or sham-exposed (2 W/kg control group) for 24 h, or exposed to RF EMF at a higher level of 3.5 W/kg (3.5 W/kg exposure group) or sham-exposed (3.5 W/kg control group).

Project description:Local percutaneous thermal ablation is frequently proposed in the management of metastatic diseases. Radiofrequency ablation (RFA) has demonstrated good results when the metastatic disease is limited and slowly evolving. The destruction of solid metastasis by RF leads to inflammatory and immunological mechanisms that remain poorly understood. These pathological events may influence the overall and anti-tumor host immune responses. The purpose of the study is to identify and quantify some immune mechanisms triggered by RFA of pulmonary metastases from colorectal cancer origin.

Project description:This study assessed changes in gene expression in 7 mouse brain regions using Illumina Mouse WG-6 (v2) beadchips after exposure to 1.9 GHz pulse-modulated radiofrequency field exposure for 4h/day for 5 days. High dose RF field exposure was whole body average SAR and brain average SAR were 1.45 W/kg and 0.16 W/kg, respectively. Total RNA isolated from the amygdala, auditory cortex, caudate, cerebellum, hippocampus, hypothalamus and medial prefrontal cortex of 1.9 GHz pulse-modulated radiofrequency field exposed mice and compared to that in sham (handled) exposed animals. An unhandled control group was also included in the study design. A total of 20 RNA samples (5 independent biological tissues for each of 4 treatment groups) were collected for each brain region. When analysis of gene expression was conducted within individual brain regions when controlling the false discovery rate (FDR), no differentially expressed genes were identified relative to the sham control. However, it must be noted that most fold changes among groups were observed to be less than 1.5 fold and this study had limited ability to detect such small changes. While some genes were differentially expressed without correction for multiple-comparisons testing, no consistent pattern of response was observed among different RF-exposure levels or among different RF-modulations. The current study provides the most comprehensive analysis of potential gene expression changes in the rodent brain in response to RF field exposure conducted to date. Within the exposure conditions and limitations of this study, no convincing evidence of consistent changes in gene expression was found in response to 1.9 GHz pulse-modulated RF field exposure.

Project description:This study assessed changes in gene expression in 7 mouse brain regions using Illumina Mouse WG-6 (v2) beadchips after exposure to 1.9 GHz continuous-wave radiofrequency field exposure for 4h/day for 5 days. High dose RF field exposure was whole body average SAR and brain average SAR were 1.36 W/kg and 0.19 W/kg, respectively. Total RNA isolated from the amygdala, caudate, cerebellum, hippocampus, hypothalamus and medial prefrontal cortex of 1.9 GHz continuous-wave radiofrequency field exposed mice and compared to that in sham (handled) exposed animals. An unhandled control group was also included in the study design. A total of 20 RNA samples (5 independent biological tissues for each of 4 treatment groups) were collected for each brain region. When analysis of gene expression was conducted within individual brain regions when controlling the false discovery rate (FDR), no differentially expressed genes were identified relative to the sham control. However, it must be noted that most fold changes among groups were observed to be less than 1.5 fold and this study had limited ability to detect such small changes. While some genes were differentially expressed without correction for multiple-comparisons testing, no consistent pattern of response was observed among different RF-exposure levels or among different RF-modulations. The current study provides the most comprehensive analysis of potential gene expression changes in the rodent brain in response to RF field exposure conducted to date. Within the exposure conditions and limitations of this study, no convincing evidence of consistent changes in gene expression was found in response to 1.9 GHz pulse-modulated RF field exposure.