The testis is highly sensitive to electromagnetic radiation. Sperm is the passer of male genetic material and electromagnetic radiation may cause structural and functional injury to the testis, including motility reduction, abnormality increase and ultrastructural alteration of epididymal sperm. Energy metabolism disorder in spermatogenic cells, enhancement of lipid peroxidation in the testis, excessive expression of inflammatory factors and abnormality of genetic transcription may be responsible for injury to the testis and epididymal sperm. This paper reviews the progress made in this field and the preventive measures against the injury.
Animals ; Epididymis ; radiation effects ; Humans ; Male ; Radiation ; Rats ; Rats, Sprague-Dawley ; Sperm Count ; Sperm Motility ; radiation effects ; Testis ; radiation effects

OBJECTIVETo investigate the influences of mobile phone radiation on the quality and DNA methylation of human sperm in vitro.

METHODSAccording to the fifth edition of the WHO Laboratory Manual for the Examination and Processing of Human Semen, we randomly selected 97 male volunteers with normal semen parameters and divided each semen sample from the subjects into two equal parts, one exposed to mobile phone radiation at 1950 M Hz, SAR3. 0 W/kg for 3 hours while the other left untreated as the control. We obtained routine semen parameters as well as the acrosomal reaction ability, apoptosis and DNA methylation of sperm, and compared them between the two groups.

RESULTSCompared with the control, the radiation group showed significantly decreased progressive sperm motility ([36.64 ± 16.93] vs [27.56 ± 16.92]%, P < 0.01) and sperm viability ([63.72 ± 16.35] vs [54.31 ± 17.35]%, P < 0.01) and increased sperm head defects ([69.92 ± 4.46] vs [71.17 ± 4.89]%, P < 0.05), but no significant differences in sperm acrosomal reaction ([66.20 ± 6.75] vs [64.50 ± 3.47]%, P > 0.05). The early apoptosis rate of sperm cells was remarkably higher in the radiation group ([6.89 ± 9.84]%) than in the control ([4.44 ± 5.89]%) (P < 0.05). However, no statistically significant differences were found between the control and radiation groups in the DNA methylation patterns of the paternal imprinting gene H19 ICR ([0.60 ± 0.02] vs [1.40 ± 0.03]%, P > 0.05) or the maternal imprinting gene KvDMR1 ([0.00 ± 0.00] vs [1.80 ± 0.031%, P > 0.05).

CONCLUSIONMobile phone radiation reduces the progressive motility and viability of human sperm and increases sperm head defects and early apoptosis of sperm cells.

Cell Phone ; DNA Methylation ; radiation effects ; Humans ; In Vitro Techniques ; Male ; Semen ; radiation effects ; Semen Analysis ; Sperm Head ; radiation effects ; Sperm Motility ; radiation effects ; Spermatozoa ; cytology ; radiation effects

With the popularized use cell phones, more and more concern has been aroused over the effects of their radiation on human health, particularly on male reproduction. Cell phone radiation may cause structural and functional injuries of the testis, alteration of semen parameters, reduction of epididymal sperm concentration and decline of male fertility. This article presents an overview on the impact of cell phone radiation on male reproduction.
Cell Phone ; DNA Damage ; Epididymis ; radiation effects ; Humans ; Male ; Oxidative Stress ; Semen ; radiation effects ; Sperm Count ; Sperm Motility ; radiation effects ; Testis ; radiation effects

OBJECTIVETo investigate the effects of extremely low frequency electromagnetic fields (ELF EMFs) on male reproduction in mice.

METHODS94 adult male mice were exposed to 50 Hz sinusoidal electromagnetic fields of 0.2, 3.2 or 6.4 mT for 2 weeks or 4 weeks. Testicular histology and weight, sperm amount, sperm motility and morphology were measured. The percentages of different ploidy cells and cell phases, and DNA content of testis cells were estimated by flow cytometry. The micronucleus rate of bone-marrow cell was also observed.

RESULTSThe testicular weight of the mice exposed to 6.4 mT for 4 weeks [(76.06 +/- 32.25) mg] was significantly lower than that of the control [(111.44 +/- 19.99) mg, P < 0.05]; no significant histopathological changes were observed on the testis in EMFs exposed mice;the sperm amount was decreased after EMFs exposure for 4 weeks, and those of the mice exposed to 0.2 mT and 6.4 mT for 4 weeks [(4.87 +/- 0.94) x 10(6)/ml and (4.30 +/- 1.89) x 10(6)/ml respectively] were significantly lower than that of the control [(6.67 +/- 0.70) x 10(6)/ml, P < 0.05]; the rates of sperm motility also showed a decline. After 0.2, 3.2 or 6.4 mT EMFs exposure for 2 weeks, the deformity rates of sperm [(7.416 +/- 3.352)%, (6.862 +/- 2.947)% and (8.112 +/- 4.615)% respectively] were significantly higher than that of the control [(4.098 +/- 2.028)%, P < 0.01]. Similarly, those of the mice exposed for 4 weeks [(10.267 +/- 3.836)%, (11.027 +/- 7.059)%, (8.814 +/- 3.678)% respectively] were higher than that of the control [(3.714 +/- 1.830)%]. After 6.4 mT exposure for 2 weeks, the percentages of 1C testis cells [(69.56 +/- 4.07)%] was significantly lower than that of the control [(73.45 +/- 3.10)%, P < 0.05]. There were not any remarkable changes in those of 2C, 4C cells. DNA content in different ploidy cells of the mice exposed to 6.4 mT was decreased. Moreover, the cell percentage in S phase was increased significantly (P < 0.01).

CONCLUSIONELF EMFs exposure may have some adverse effects on reproduction in mice.

Animals ; DNA ; metabolism ; Electromagnetic Fields ; Male ; Mice ; Random Allocation ; Reproduction ; radiation effects ; Sperm Count ; Sperm Motility ; radiation effects ; Spermatozoa ; cytology ; metabolism ; radiation effects ; Testis ; cytology ; radiation effects

Animals ; Down-Regulation ; radiation effects ; Heavy Ion Radiotherapy ; adverse effects ; Infertility, Male ; etiology ; Male ; Mice ; Random Allocation ; Sperm Motility ; radiation effects ; Spermatozoa ; metabolism ; radiation effects ; Tubulin ; metabolism

OBJECTIVETo study the effects of radar radiation on sperm quality.

METHODSA total of 348 infertile seamen were divided into 4 experimental groups according to their different lengths of exposure to radar radiation: Group 1 (n = 128) exposed for 12-36 months, Group 2 (n = 58) 37-72 m, Group 3 (n = 47) 73-108 m, Group 4 (n = 19) 109 m or more and Group 5 (n = 96) 48 m or more but free from the exposure for 6 months by then. Another 35 non-marine normal males were recruited as Control Group 1, and the first four experimental groups (n = 252) were taken as Control Group 2. Semen samples were collected from the subjects and analyzed statistically.

RESULTSCompared with the normal control, sperm concentration, sperm motility and the percentage of grade a sperm were significantly lower (P < 0.01), and the percentages of grade d and abnormal sperm significantly higher (P < 0.01) in the experimental groups. In Group 5, obvious recovery was noted in sperm morphology (P < 0.01) and motility (P < 0.05), but significant differences were seen with the normal control group in sperm concentration (P < 0.05), sperm motility and the percentage of grade a and b sperm and that of abnormal sperm (P < 0. 01).

CONCLUSIONRadar radiation damages sperm quality, as shown in the reduction of sperm motility and elevation of sperm abnormality. Cease from the exposure may effect an easy recovery in sperm morphology.

Adult ; Humans ; Infertility, Male ; physiopathology ; Male ; Microwaves ; Middle Aged ; Naval Medicine ; Occupational Exposure ; analysis ; Radar ; Semen ; cytology ; radiation effects ; Sperm Count ; Sperm Motility ; physiology ; radiation effects

OBJECTIVETo explore the relationship between physical and biological effects of alternating magnetic field and study the influence of the magnetic field on the reproductive function of murine testes.

METHODSThirty ICR mice were randomized into 5 groups: normal control, X-ray radiation, weak magnetic field (1000 Hz), 1 h strong magnetic field and 2 h strong magnetic field (2000 Hz). The mice were sacrificed at 7 days after the exposure for the analysis of testicular sperm motility, observation of histopathological changes in the testis by HE staining and evaluation of the changes by modified Johnsen grade criteria.

RESULTSThe rates of sperm motility were (42.37 +/- 10.24)% in the normal control group, (39.00 +/- 12.35)% in the X-ray radiation group, (36.00 +/- 17.28)% in the weak magnetic field group, (10.72 +/- 5.67)% in the 1 h strong magnetic field group and (4.44 +/- 2.87)% in the 2 h strong magnetic field group, respectively. Johnsen's scores decreased and the testis damage increased in a dose- and time-dependent manner.

CONCLUSIONMagnetic field, either strong or weak, may damage the testis function by inducing injury to seminiferous tubules and Leydig cells, thickening of the basal membrane, derangement, exfoliation, massive apoptosis and necrosis of spermatogenic cells in the lumen, situation of the epididymis, and consequently the absence of sperm.

Animals ; Electromagnetic Fields ; adverse effects ; Leydig Cells ; pathology ; Male ; Mice ; Mice, Inbred ICR ; Sperm Motility ; Testis ; cytology ; pathology ; radiation effects

OBJECTIVETo determine whether laser-assisted immobilization of sperm damages sperm DNA.

METHODSTwenty-three semen samples were selected from an IVF program. Then normal spermatozoa were obtained by swimming-up method and immobilized with the tail by 0.45 ms pulse laser. Terminal deoxynucleotidyl transferase mediated dUTP nick end labeling (TUNEL) and single cell gel electrophoresis (SCGE) were used to detect sperm DNA damage.

RESULTSThere was no significant difference either before and after laser treatment in the percentage of TUNEL-positive spermatozoa ([1.32 +/- 0.61]% vs [1.41 +/- 0.51]%, P > 0.05) or in SCGE ([1.59 +/- 0.70]% vs [1.83 +/- 0.68]%, P > 0.05).

CONCLUSIONLaser-assisted sperm immobilization may cause no direct damage to the sperm DNA.

Comet Assay ; DNA Damage ; radiation effects ; Humans ; In Situ Nick-End Labeling ; In Vitro Techniques ; Lasers ; Male ; Semen ; radiation effects ; Sperm Motility ; Spermatozoa

Objective: To investigate the improving effect of astaxanthin (AST) on the sperm quality of rats with ornidazole (ORN)-induced oligoasthenozoospermiaand its action mechanism. METHODS: Forty adult male SD rats were equally randomized into groups A (solvent control), B (low-dose ORN ［400 mg/（kg·d）］), C (high-dose ORN ［800 mg/（kg·d）］), D (low-dose ORN ［400 mg/（kg·d）］ + AST ［20 mg/（kg·d）］), and E (high-dose ORN ［800 mg/（kg·d）］ + AST ［20 mg/（kg·d）］), all treated intragastrically for3 weeks.After treatment, the epididymal tails ononeside was taken for determination of sperm concentration and activity, and the epididymideson the other side harvested for measurement of the activities of GSH-Px, GR, CAT and SOD and the MDA contentin the homogenate. RESULTS: Compared with group A, sperm motilityin the epididymal tail andGSH-Px and SOD activities in theepididymiswere markedly decreased while the MDAcontent significantlyincreased in group B (P<0.05), spermmotility and concentrationin the epididymal tail, testisindex, and the activities of GSH-Px, GR, CAT and SOD in the epididymis were remarkably reduced while theMDA contentsignificantly increased in group C(P<0.05). In comparison with group B, group D showed markedly increased sperm motility (［45.3±8.7］% vs ［66.3±8.9］%, P<0.05) in the epididymal tail and SOD activity in the epididymis (［116.7±25.3］ U/mg prot vs ［146.1±23.8］ U/mg prot, P<0.05), decreased MDA content(［1.68±0.45］ nmol/mg prot vs ［1.19±0.42］ nmol/mg prot, P<0.05).Compared with group C, group Eexhibited significant increases in the weight gained (［89.0±9.5］ vs ［99.9±4.1］ %, P<0.05) and sperm motility (［17.9±3.5］% vs ［27.3±5.3］ %, P<0.05) but a decrease in the content of MDA (［2.03±0.30］ nmol/mg prot vs ［1.52±0.41］ nmol/mg prot, P<0.05). CONCLUSIONS AST can improve spermquality in rats with ORN-inducedoligoasthenozoospermia, which may be associated with its enhancing effect on the antioxidant capacity of the epididymis.
Animals ; Antioxidants ; pharmacology ; Asthenozoospermia ; prevention & control ; Epididymis ; drug effects ; metabolism ; Male ; Oligospermia ; prevention & control ; Ornidazole ; Oxidative Stress ; Protective Agents ; pharmacology ; Radiation-Sensitizing Agents ; Random Allocation ; Rats ; Rats, Sprague-Dawley ; Sperm Count ; Sperm Motility ; Spermatozoa ; drug effects ; metabolism ; Xanthophylls ; pharmacology

BACKGROUND: Exposure to the ionizing radiation (IR) encountered outside the magnetic field of the Earth poses a persistent threat to the reproductive functions of astronauts. The potential effects of space IR on the circadian rhythms of male reproductive functions have not been well characterized so far. METHODS: Here, we investigated the circadian effects of IR exposure (3 Gy X-rays) on reproductive functional markers in mouse testicular tissue and epididymis at regular intervals over a 24-h day. For each animal, epididymis was tested for sperm motility, and the testis tissue was used for daily sperm production (DSP), testosterone levels, and activities of testicular enzymes (glucose-6-phosphate dehydrogenase (G6PDH), sorbitol dehydrogenase (SDH), lactic dehydrogenase (LDH), and acid phosphatase (ACP)), and the clock genes mRNA expression such as Clock, Bmal1, Ror-α, Ror-β, or Ror-γ. RESULTS: Mice exposed to IR exhibited a disruption in circadian rhythms of reproductive markers, as indicated by decreased sperm motility, increased daily sperm production (DSP), and reduced activities of testis enzymes such as G6PDH, SDH, LDH, and ACP. Moreover, IR exposure also decreased mRNA expression of five clock genes (Clock, Bmal1, Ror-α, Ror-β, or Ror-γ) in testis, with alteration in the rhythm parameters. CONCLUSION These findings suggested potential health effects of IR exposure on reproductive functions of male astronauts, in terms of both the daily overall level as well as the circadian rhythmicity.
ARNTL Transcription Factors/genetics* ; Acid Phosphatase ; Animals ; CLOCK Proteins/genetics* ; Circadian Rhythm/radiation effects* ; Epididymis/radiation effects* ; Gene Expression/radiation effects* ; Genitalia, Male/radiation effects* ; Glucosephosphate Dehydrogenase ; L-Iditol 2-Dehydrogenase ; L-Lactate Dehydrogenase ; Male ; Mice ; Mice, Inbred C57BL ; Models, Animal ; Nuclear Receptor Subfamily 1, Group F, Member 1/genetics* ; Nuclear Receptor Subfamily 1, Group F, Member 2/genetics* ; Nuclear Receptor Subfamily 1, Group F, Member 3/genetics* ; RNA, Messenger/genetics* ; Radiation Exposure ; Radiation, Ionizing ; Reproductive Physiological Phenomena/radiation effects* ; Sperm Motility/radiation effects* ; Spermatozoa/radiation effects* ; Testis/radiation effects*