Evaluation of the genotoxicity of cell phone radiofrequency radiation in male and female rats and mice following subchronic exposure

Figure S1 A – D. Consistency in scoring brain tissues meeting criteria for a positive call. (A) 100‐cell versus 150‐cell scoring method for male mouse frontal cortex, individual animal data. Each bar represents average % tail DNA per mouse. Error bars not shown for ease of comparison. (B) 100‐cell versus 150‐cell scoring method for male mouse frontal cortex tissue, dose group data. Each bar represents mean % tail DNA (+/‐ SE) per group. (C) 100‐cell versus 150‐cell scoring method for male rat hippocampus. Each bar represents average % tail DNA per rat. Error bars not shown for ease of comparison. (D) 100‐cell versus 150‐cell scoring method for male rat hippocampus, dose group data. Each bar represents mean % tail DNA (+/‐ SE) per group. Note that although including hedgehogs in the 150‐cell method increased the % tail DNA values, the overall pattern and results remained the same. Although male rat hippocampus was positive only for the 100‐cell data (Figures 1G, H), the overall difference between the two scoring methods was small.

Figure S2 A – D. Representative comparison of the two comet assay scoring approaches in frontal cortex cells of male mice. Male mouse frontal cortex met the criteria for a positive call with both methods. The central horizontal bar indicates the mean; the vertical bar indicates the standard error of the mean. Each dot represents a % tail DNA value from one comet. Hedgehogs were excluded in the 100‐cell scoring method and were included in the 150‐cell method. Note: including hedgehogs results in capture of a wider range of % tail DNA.

Figure S3 A – D. Representative comparison of the two comet assay scoring approaches in hippocampal cells of male rats. Male rat hippocampus met the criteria for a positive call with the 100‐cell scoring approach. The central horizontal bar indicates the mean and the vertical bar indicates the standard error of the mean. Each dot represents a % tail DNA value from one comet. Hedgehogs were excluded in the 100‐cell scoring method and were included in the 150‐cell method. Note: including cells suspected to be hedgehogs at low scanning power results in capture of a wider range of % tail DNA. Rat tissues tended to show more hedgehogs than tissues from mice.

Figure S4 A. Shown are the mean % tail DNA data for each exposure for frontal cortex, hippocampus, cerebellum, liver, and blood tissues for male rats exposed to CDMA (top row) or GSM (bottom row) cell phone RFR modulations. The median value is marked with a + sign. Five animals are represented in each exposure group.

Figure S4 B. Shown are the mean % tail DNA data for each exposure for frontal cortex, hippocampus, cerebellum, liver, and blood tissues for female rats exposed to CDMA (top row) or GSM (bottom row) cell phone RFR modulations. The median value is marked with a + sign. Five rats are represented in each exposure except for sham, 1.5 W/kg GSM, and 3.0 W/kg GSM groups for hippocampal tissue, which are represented by 4 rats per group. One rat in the sham exposure group was omitted because it had a biologically implausible value of 56.1% tail DNA. One rat in the 1.5 W/kg GSM group and one rat in the 3.0 W/kg GSM group were omitted from analysis due to a labeling error during tissue collection.

Figure S4 C. Shown are the mean % tail DNA data for each exposure for frontal cortex, hippocampus, cerebellum, liver, and blood tissues for male mice exposed to CDMA (top row) or GSM (bottom row) cell phone RFR modulations. The median value is marked with a + sign. Five mice are represented in each exposure group.

Figure S4 D. Shown are the mean % tail DNA data for each exposure for frontal cortex, hippocampus, cerebellum, liver, and blood tissues for female mice exposed to CDMA (top row) or GSM (bottom row) cell phone RFR modulations. The median value is marked with a + sign. Five mice are represented in each exposure group.

Table S1 Frequency of Micronuclei in Peripheral Blood Erythrocytes of Rats Following Exposure to CDMA‐ or GSM‐Modulated Cell Phone RFR for 19 Weeks^a

Table S2 Frequency of Micronuclei in Peripheral Blood Erythrocytes of Mice Following Exposure to CDMA‐ or GSM‐Modulated Cell Phone RFR for 14 Weeks^a