234 JOURNAL OF THE SOCIETY OF COSMETIC CHEMISTS 16 ?- õ 8 • 4 o :..,:: .• : ::.: • ß :.: : • Cheeks Forearms Legs Blacks Whites Figure 3. Rate of change in continuous capacitance (mean + SD) found from the slope of the capacitance vs time regression line for the first 60 seconds of data collection. Asterisk indicates significant difference (p 0.05). ELASTIC RECOVERY Black skin demonstrated higher elastic recovery than white skin on the cheeks (p 0.05). On the legs, the difference was not statistically significant (Figure 4). pH On the cheeks, pH of black skin was significantly lower than that of white skin (5.15 vs 5.52). On the legs, the difference (5.56 vs 5.75) was not statistically significant (Figure 5). DESQUAMATION INDEX The desquamation index was found to be lower on the cheeks (p 0.05) and forehead (p 0.05) for blacks as compared to whites. However, no significant differences were found on the legs (Figure 6). VISUAL SCORES Differences were significantly lower for white skin on the forearms (p 0.05) and legs (p 0.05). On the face, there were no statistical differences between blacks and whites (Figure 7). AEROBES Staphylococci sp. principally made up the microflora. There were no significant racial differences.

COMPARISON OF BLACK AND WHITE SKIN 235 0.18 0.135 0.09 0.045 0 Cheeks Blacks Whites Legs Figure 4. Elastic recovery (mean - SD). Asterisk represents significant difference (p 0.05). PROPIONIBACTERUM ACNES The overall density of P. acnes was greater in blacks, but the values fell just short of reaching significance (Figure 8). DISCUSSION Although the stratum corneum in black and white skin is of equal thickness (1), Weigand et al. (2) have shown that the black stratum corneum is made up of more cell layers and exhibits greater resistance to tape stripping than the white stratum corneum. Rienertson and Wheatly (3) reported increased levels of lipid content in black skin. This result was later confirmed by Weigand et al. (2). The greater number of stratum corneum cell layers and resistance to stripping demonstrated in blacks have not been explained and may involve intercellular lipids and desmosomal density. Owing to a greater number of corneocyte layers, it is reasonable that TEWL might be lower in blacks. Indeed, results from this study show that TEWL values for blacks are lower than for whites on all sites evaluated (Figure 2). Although, in one of their latest studies, Berardesca et al. (10) did not find TEWL to be significantly lower in black skin, a definite trend was observed. Blacks exhibited lower TEWL readings than Caucasians and Hispanics on the forearms (volar and dorsal). The observations of Berardesca et al. (10) are in agreement with our findings. Other reports in which TEWL was found to be higher in blacks may reflect the small sample sizes used by the investigators (7,15,16). Initial water content was found to be higher on the cheeks (p 0.05) and lower on the forearms and legs for blacks (Table I). Moisture accumulation (Table I) and the rate of moisture buildup (Figure 3) after a period of 60 seconds were found to be higher for blacks on the cheeks, but significantly lower on the forearms and legs. The rate of increase in continuous capacitance is inversely related to skin barrier competence (12).