This study examined the impact of 935MHz phone-simulating electromagnetic radiation on embryo implantation of pregnant mice. Each 7-week-old Kunming (KM) female white mouse was set up with a KM male mouse in a single cage for mating overnight after induction of ovulation. In the first three days of pregnancy, the pregnant mice was exposed to electromagnetic radiation at low-intensity (150 μW/cm(2), ranging from 130 to 200 μW/cm(2), for 2- or 4-h exposure every day), mid-intensity (570 μW/cm(2), ranging from 400 to 700 μW/cm(2), for 2- or 4-h exposure every day) or high-intensity (1400 μW/cm(2), ranging from 1200 to 1500 μW/cm(2), for 2- or 4-h exposure every day), respectively. On the day 4 after gestation (known as the window of murine embryo implantation), the endometrium was collected and the suspension of endometrial glandular cells was made. Laser scanning microscopy was employed to detect the mitochondrial membrane potential and intracellular calcium ion concentration. In high-intensity, 2- and 4-h groups, mitochondrial membrane potential of endometrial glandular cells was significantly lower than that in the normal control group (P<0.05). The calcium ion concentration was increased in low-intensity 2-h group but decreased in high-intensity 4-h group as compared with the normal control group (P<0.05). However, no significant difference was found in mitochondrial membrane potential of endometrial glandular cells between low- or mid-intensity groups and the normal control group, indicating stronger intensity of the electromagnetic radiation and longer length of the radiation are required to inflict a remarkable functional and structural damage to mitochondrial membrane. Our data demonstrated that electromagnetic radiation with a 935-MHz phone for 4 h conspicuously decreased mitochondrial membrane potential and lowered the calcium ion concentration of endometrial glandular cells. It is suggested that high-intensity electromagnetic radiation is very likely to induce the death of embryonic cells and decrease the chance of their implantation, thereby posing a high risk to pregnancy.

Objective To explore the perinatal outcome of vaginal birth after cesarean (VBAC) in women with advanced age.Methods Totally 2 587 women delivered after one or two prior cesarean sections (gestational age≥28 weeks) in the First Affiliated Hospital of Kunming Medical University from July 2013 to February 2017.909 trial of labor after cesarean(TOLAC) cases of singleton pregnancy with one prior cesarean section were studied retrospectively.According to the age,of the 909 TOLAC cases,237 were the advanced age group,and 672 cases were the low age group.The maternal and neonatal outcomes between the two groups were compared.Results The percentage of TOLAC in women with advanced age was 32.4％ (237/731),and VBAC rate was 88.2％ (209/237).The percentage of TOLAC in younger women was 36.2％ (672/1 856),and VBAC rate was 82.4％ (554/672).The difference of the TOLAC rate between the two groups was not significant (P＞0.05),and the VBAC rate of the advanced age group was higher than the low age group (P＜0.05).In the comparison of the two groups,the proportion of bachelor degree or above(55.7％,132/ 237),the prepregnancy BMI (22.4±3.0) kg/m2,pregnant interval time (68.5±38.3) months,the proportion of gestational hypertension (8.4％,20/237),the proportion of gestational diabetes(34.6％,82/237) and the rate of the neonatal ICU admission (18.1％,43/237) in the advanced age group were higher than those of the low age group (P＜0.05),respectively.And there were no significant differences in the rate of postpartum hemorrhage,the rate of postpartum hemorrhage≥1 500 ml,the rate of postpartum transfusion,puerperal morbidity,neonatal birth weight,neonatal 5 min Apgar score＜7 score,umbilical artery blood pH＜7.0,neonatal tracheal intubation and respiratory distress syndrome (all P＞0.05).In all TOLAC cases,the rate of uterine rupture was 0.11％(1/909) and there was no maternal and neonatal death.Conclusion VBAC is a safe and feasible way of delivery for singleton pregnancy after one prior cesarean section in women with advanced age.

This study examined the impact of 935MHz phone-simulating electromagnetic radiation on embryo implantation of pregnant mice. Each 7-week-old Kunming (KM) female white mouse was set up with a KM male mouse in a single cage for mating overnight after induction of ovulation. In the first three days of pregnancy, the pregnant mice was exposed to electromagnetic radiation at low-intensity (150 μW/cm(2), ranging from 130 to 200 μW/cm(2), for 2- or 4-h exposure every day), mid-intensity (570 μW/cm(2), ranging from 400 to 700 μW/cm(2), for 2- or 4-h exposure every day) or high-intensity (1400 μW/cm(2), ranging from 1200 to 1500 μW/cm(2), for 2- or 4-h exposure every day), respectively. On the day 4 after gestation (known as the window of murine embryo implantation), the endometrium was collected and the suspension of endometrial glandular cells was made. Laser scanning microscopy was employed to detect the mitochondrial membrane potential and intracellular calcium ion concentration. In high-intensity, 2- and 4-h groups, mitochondrial membrane potential of endometrial glandular cells was significantly lower than that in the normal control group (P<0.05). The calcium ion concentration was increased in low-intensity 2-h group but decreased in high-intensity 4-h group as compared with the normal control group (P<0.05). However, no significant difference was found in mitochondrial membrane potential of endometrial glandular cells between low- or mid-intensity groups and the normal control group, indicating stronger intensity of the electromagnetic radiation and longer length of the radiation are required to inflict a remarkable functional and structural damage to mitochondrial membrane. Our data demonstrated that electromagnetic radiation with a 935-MHz phone for 4 h conspicuously decreased mitochondrial membrane potential and lowered the calcium ion concentration of endometrial glandular cells. It is suggested that high-intensity electromagnetic radiation is very likely to induce the death of embryonic cells and decrease the chance of their implantation, thereby posing a high risk to pregnancy.
Animals ; Electromagnetic Radiation ; Embryo Implantation ; physiology ; Endometrium ; physiology ; Epithelial Cells ; physiology ; Female ; Male ; Mice