Project description:To evaluate the effect of millimeter waves (MMW) exposure on the gene expression, we have employed whole genome microarray expression profiling. Neonatal primary Keratinocyte cells pooled from 3 healthy donors were exposed ex vivo, by 60.4 GHz-MMW, at an incident power density (IPD) of 20 mW/cm² (3 hours of treatment in athermic condition).No modification of keratinocyte transcriptome was observed. Considering that MMW could also impact the cell metabolism, we assessed then effect of glycolysis inhibitor 2 deoxyglucose treatment (2dG, 20 mM during 3 hours) in association with MMW co-exposure. 2dG treatment induces a high modification of the transcriptome (632 coding genes). Genes affected in their expression are linked with transcriptional repression, cellular communication and endoplasmic reticulum homeostasis. The MMW/2dG co-exposition induced a slight modification of cell transcriptome, which reflects the capacity of MMW to interfere with bioenergetic stress response. After RT-PCR validation, 6 genes (SOCS3, SPRY2, TRIB1, FAM46A, CSRNP1 and PPP1R15A) were confirmed as sensitive to MMW exposure during 2dG treatment.

Project description:Purpose: The use of millimeter waves (MMW) will likely grow exponentially in the coming years due to their future utilization in high-speed telecommunications. The question of the possible biological effects of these frequencies has been raised, and in the present study, we aimed to explore, throw an innovating RNA sequencing approach known as Bulk RNA Barcoding sequencing (BRB-seq), the difference in gene expression under exposure. Methods: Tree main exposure scenario were explored. The first one aim to compare the cellular response of two primary culture of keratinocytes (HEK and NHEK) and one keratinocyte derivate cell line (HaCaT) exposed to MMW. The second scenario explore the dose effect of gradient of incident power density on gene expression in cell line. The last one explore the exposure time at the new exposure limit for the general population. Results: Our data shows that gene expression is quite different between the cellular models used, which validates the method used. However, the exposure scenarios demonstrates that the main effect was the heat effect associated with high power MMW. Some genes were also altered by exposure. Altered expression of 2 genes was confirmed with qRT–PCR. Conclusions: These results show that acute exposure to MMW has low effect on gene expression.

Project description:Millimetre-wave (MMW) frequencies of the electromagnetic spectrum are increasingly being adopted in modern technologies including mobile communications, networking, and security screening. These frequencies are absorbed by the outer layers of the skin, however the biological effects are not well characterised. Thus, as emerging technologies increase human exposure, understanding the effects of MMWs on biological material and cell biology in the skin is critical in determining safe exposure levels. Here, we report on the exposure of primary human dermal fibroblasts to MMWs; we find that the radiation triggers genomic and transcriptomic alterations. In particular, repeated 60 GHz MMW exposures at 2.6 mW cm-2, 46.8 J cm-2 doses, trigger a physiological response in human fibroblasts distinct from conventional cytokine-induced stimulation. Our results show that high dose MMWs induce non-thermal transcriptomic alterations with simultaneous changes in DNA structural dynamics including formation of G-quadruplex and i-motif secondary structures, but not DNA damage.

Project description:Millimeter Waves Modulate the Transcriptome in Human Fibroblasts

Project description:Transcriptional landscape of human keratinocyte models exposed to 60-GHz millimeter-waves

Project description:Radiofrequency radiations constitute a new form of environmental pollution. Among them, millimeter waves (MMW) will be widely used in the near future for high speed communication systems. This study aimed therefore to evaluate the biocompatibility of MMW at 60 GHz. For this purpose, we used a whole gene expression approach to assess the effect of acute 60 GHz exposure on primary cultures of human keratinocytes. Controls were performed to dissociate the electromagnetic from the thermal effect of MMW. Microarray data were validated by RT-PCR, in order to ensure the reproducibility of the results. MMW exposure at 20 mW/cm2, corresponding to the maximum incident power density authorized for public use (local exposure averaged over 1 cm2), led to an increase of temperature and to a strong modification of keratinocyte gene expression (665 genes differentially expressed). Nevertheless, when temperature is artificially maintained constant, no modification in gene expression was observed after MMW exposure. However, a heat shock control did not mimic exactly the MMW effect, suggesting a slight but specific electromagnetic effect under hyperthermia conditions (34 genes differentially expressed). By RT-PCR, we analyzed the time course of the transcriptomic response and 7 genes have been validated as differentially expressed: ADAMTS6, NOG, IL7R, FADD, JUNB, SNAI2 and HIST1H1A. Our data evidenced a specific electromagnetic effect of MMW, which is associated to the cellular response to hyperthermia. This study raises the question of co-exposures associating radiofrequencies and other environmental sources of cellular stress.

Project description:The resolution along the propagation direction of far field imagers can be much smaller than the wavelength by exploiting coherent interference phenomena. We demonstrate a height profile precision as low as 31 nm using wavelengths between 0.375 mm and 0.5 mm (corresponding to 0.6 THz-0.8 THz) by evaluating the Fabry-Pérot oscillations within surface-structured samples. We prove the extreme precision by visualizing structures with a height of only 49 nm, corresponding to 1:7500 to 1:10000 vacuum wavelengths, a height difference usually only accessible to near field measurement techniques at this wavelength range. At the same time, the approach can determine thicknesses in the centimeter range, surpassing the dynamic range of any near field measurement system by orders of magnitude. The measurement technique combined with a Hilbert-transform approach yields the (optical) thickness extracted from the relative phase without any extraordinary wavelength stabilization.

Project description:ObjectiveGlycolytic inhibition via 2-deoxy-D-glucose (2DG) has potential therapeutic benefits for a range of diseases, including cancer, epilepsy, systemic lupus erythematosus (SLE), and rheumatoid arthritis (RA), and COVID-19, but the systemic effects of 2DG on gene function across different tissues are unclear.MethodsThis study analyzed the transcriptional profiles of nine tissues from C57BL/6J mice treated with 2DG to understand how it modulates pathways systemically. Principal component analysis (PCA), weighted gene co-network analysis (WGCNA), analysis of variance, and pathway analysis were all performed to identify modules altered by 2DG treatment.ResultsPCA revealed that samples clustered predominantly by tissue, suggesting that 2DG affects each tissue uniquely. Unsupervised clustering and WGCNA revealed six distinct tissue-specific modules significantly affected by 2DG, each with unique key pathways and genes. 2DG predominantly affected mitochondrial metabolism in the heart, while in the small intestine, it affected immunological pathways.ConclusionsThese findings suggest that 2DG has a systemic impact that varies across organs, potentially affecting multiple pathways and functions. The study provides insights into the potential therapeutic benefits of 2DG across different diseases and highlights the importance of understanding its systemic effects for future research and clinical applications.

Project description:Cancer chemotherapy treatment often leads to hair loss, which may be prevented by cooling the scalp during drug administration. The current hypothesis for the hair preservative effect of scalp cooling is that cooling of the scalp skin reduces blood flow (perfusion) and chemical reaction rates. Reduced perfusion leads to less drugs available for uptake, whereas the reduced temperature decreases uptake of and damage by chemotherapy. Altogether, less damage is exerted to the hair cells, and the hair is preserved. However, the two mechanisms in the hypothesis have not been quantified yet. To quantify the effect of reduced drug damage caused by falling temperatures, we investigated the effect of local drug concentration and local tissue temperature on hair cell damage using in vitro experiments on keratinocytes. Cells were exposed for 4 h to a wide range of doxorubicin concentrations. During exposure, cells were kept at different temperatures. Cell viability was determined after 3 d using a viability test. Control samples were used to establish a concentration-viability curve. Results show that cell survival is significantly higher in cooled cells (T < 22 degrees C) than in non-cooled cells (T = 37 degrees C), but no significant differences are visible between T = 10 degrees C and T = 22 degrees C. Based on this result and previous work, we can conclude that there is an optimal temperature in scalp cooling. Further cooling will only result in unnecessary discomfort for the patient and should therefore be avoided.

Project description:We demonstrate broadband non-resonant squeezing of terahertz (THz) waves through an isolated 2-nm-wide, 2-cm-long slit (aspect ratio of 10(7)), representing a maximum intensity enhancement factor of one million. Unlike resonant nanogap structures, a single, effectively infinitely-long slit passes incident electromagnetic waves with no cutoff, enhances the electric field within the gap with a broad 1/f spectral response, and eliminates interference effects due to finite sample boundaries and adjacent elements. To construct such a uniform, isolated slit that is much longer than the millimeter-scale spot of a THz beam, we use atomic layer lithography to pattern vertical nanogaps in a metal film over an entire 4-inch wafer. We observe an increasing field enhancement as the slit width decreases from 20 nm to 2 nm, in agreement with numerical calculations.