Mobile phone related articles are
Please note that a publication can be assigned to several endpoints, i.e. the sum of publications from the individual thematic points and subpoints can be greater than the total sum of actual publications.
| Authors | Year | Exposed system | Endpoints | Frequency range | SAR | Exposure duration | Parameters |
|---|---|---|---|---|---|---|---|
| Kouzmanova M et al. | 2007 | intact cell/cell culture, erythrocytes suspension | membrane stability | 902 MHz | - | continuous for 20 min | digital mobile phone, GSM, mobile communications |
| Capri M et al. | 2004 | intact cell/cell culture, human peripheral blood mononuclear cells | effects on human peripheral blood mononuclear cells (apoptosis, mitochondrial membrane potential; heat shock protein 70) | 1,800 MHz | 1.4–2 W/kg | intermittent, 10 min on/20 min off, for 44 h | GSM, mobile communications |
| Xu S et al. | 2006 | intact cell/cell culture, hippocampal neurons | activity and functional changes of glutamate receptor channels | 1,800 MHz | 2.4 W/kg | repeated daily exposure, 15 min/day, for 8 days | digital mobile phone, GSM, mobile communications, microwaves |
| In SM et al. | 2013 | intact cell/cell culture, tissue sample: nasal mucosa cells, nasal epithelial cells | function of cilia of nasal mucosa | 1.8 GHz | 1 W/kg | continuous for 3 days | mobile phone, mobile communications, RF field, CW continuous wave |
| Liu K et al. | 2014 | intact cell/cell culture, GC-2 cells (murine spermatocyte-derived cell line) | - | 1,800 MHz | 1–4 W/kg | intermittent for 24 hours (5 min on and 10 min off) | mobile phone, GSM, mobile communications |
| Lu Y et al. | 2014 | intact cell/cell culture, N9 cells (mouse microglial cells) and C8-D1A cells (mouse astrocyte type I cells) | proinflammatory protein expression and gene expression; nitric oxide release; STAT3 activation, activation of microglia and astrocytes | 1,800 MHz | 2 W/kg | intermittent for 1, 3, 6, 12, or 24 hours (5 min on and 10 min off) | mobile phone, mobile communications, RF field, PW pulsed wave |
| Alahmad YM et al. | 2018 | intact cell/cell culture, FaDu and SCC25 cells (human head and neck cancer cell lines), animal, chicken/White Leghorn (eggs) | - | 1,800 MHz | - | - | mobile communications, mobile phone |
| Li R et al. | 2018 | intact cell/cell culture | - | 1,800 MHz | - | - | mobile communications, GSM, RF field |
| Arthamin MZ et al. | 2020 | intact cell/cell culture, human peripheral blood mononuclear cells and whole blood | - | 1,800 MHz | - | - | mobile communications, mobile phone, RF field |
| Joushomme A et al. | 2022 | intact cell/cell culture | - | 1,800 MHz | - | - | mobile communications, UMTS, GSM, LTE, 4G, CW continuous wave, PW pulsed wave, W-LAN/WiFi, also other exposures without EMF, co-exposure |
| Upadhyaya C et al. | 2022 | plant, tomato (<i>Solanum lycopersicum</i> L.) | - | 1,800 MHz | - | - | mobile communications, CW continuous wave |
| Lin YY et al. | 2017 | intact cell/cell culture, TM3 cells (mouse Leydig cell line) | - | 1,950 MHz | - | - | mobile communications, GSM, RF field |
| Esmekaya MA et al. | 2013 | intact cell/cell culture, human breast fibroblasts | cell viability, apoptosis, mitochondrial membrane potential | 2.1 GHz | 0.607 W/kg | continuous for 4 or 24 hours | W-CDMA, mobile communications, microwaves |
| Canovi A et al. | 2023 | intact cell/cell culture, primary cortical neurons (of rat embryos) | - | 3.5 GHz | - | - | mobile communications, 5G, CW continuous wave, RF field, also other exposures without EMF |
| Havas F et al. | 2024 | intact cell/cell culture, primary normal human epidermal keratinocytes (NHEK) | - | 6 GHz | - | - | mobile communications, 5G, co-exposure, also other exposures without EMF |
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