BACKGROUND: Since 1950, the greatest increase in cutaneous melanoma incidence in fair-skinned males took place on the trunk and on the head and neck, whereas in females, it took place on the limbs, mainly on the lower limbs. We examined the influence of sex on numbers and size of nevi on different body sites in white European schoolchildren. METHODS: Information about each holiday period since birth to interview was recorded from parents of six hundred twenty-eight 6- to 7-year-old children in four European cities (Brussels (Belgium), Bochum (Germany), Lyons (France), and Rome (Italy)). Number and anatomic location of small (2-4.9 mm) and large (>/=5 mm) nevi and individual susceptibility to sunlight were independently assessed. RESULTS: After adjustment for host characteristics, sun exposure, and sun protection habits, males had 7% [95% confidence interval (95% CI), -7 to 19] more small nevi than females. However, compared to females, numbers of small nevi were increased by 17% (95% CI, 1-31) on the head and neck and by 16% (95% CI, 2-27) on the trunk and shoulders. In contrast, in males, the number of small nevi on upper limbs was decreased by -5% (95% CI, -26 to 13), and on lower limbs by -8% (95% CI, -34 to 13). The number of large nevi was 6% higher in males than in females (95% CI, -26 to 30). CONCLUSIONS: The sex differences in small nevus distribution in schoolchildren reflect the sex differences in the anatomic distribution of melanoma in adults. Sex differences in sun exposure behaviors, dressing, and clothing would just add their effects to the sex-dependent inherited propensity to develop nevi on a given body site. These results reinforce the hypothesis by which childhood would be a decisive period for the occurrence of sun-induced biological events implicated in the genesis of cutaneous melanoma.
BACKGROUND: Since 1950, the greatest increase in cutaneous melanoma incidence in fair-skinned males took place on the trunk and on the head and neck, whereas in females, it took place on the limbs, mainly on the lower limbs. We examined the influence of sex on numbers and size of nevi on different body sites in white European schoolchildren. METHODS: Information about each holiday period since birth to interview was recorded from parents of six hundred twenty-eight 6- to 7-year-old children in four European cities (Brussels (Belgium), Bochum (Germany), Lyons (France), and Rome (Italy)). Number and anatomic location of small (2-4.9 mm) and large (>/=5 mm) nevi and individual susceptibility to sunlight were independently assessed. RESULTS: After adjustment for host characteristics, sun exposure, and sun protection habits, males had 7% [95% confidence interval (95% CI), -7 to 19] more small nevi than females. However, compared to females, numbers of small nevi were increased by 17% (95% CI, 1-31) on the head and neck and by 16% (95% CI, 2-27) on the trunk and shoulders. In contrast, in males, the number of small nevi on upper limbs was decreased by -5% (95% CI, -26 to 13), and on lower limbs by -8% (95% CI, -34 to 13). The number of large nevi was 6% higher in males than in females (95% CI, -26 to 30). CONCLUSIONS: The sex differences in small nevus distribution in schoolchildren reflect the sex differences in the anatomic distribution of melanoma in adults. Sex differences in sun exposure behaviors, dressing, and clothing would just add their effects to the sex-dependent inherited propensity to develop nevi on a given body site. These results reinforce the hypothesis by which childhood would be a decisive period for the occurrence of sun-induced biological events implicated in the genesis of cutaneous melanoma.
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Authors: R E Neale; P W Barnes; T M Robson; P J Neale; C E Williamson; R G Zepp; S R Wilson; S Madronich; A L Andrady; A M Heikkilä; G H Bernhard; A F Bais; P J Aucamp; A T Banaszak; J F Bornman; L S Bruckman; S N Byrne; B Foereid; D-P Häder; L M Hollestein; W-C Hou; S Hylander; M A K Jansen; A R Klekociuk; J B Liley; J Longstreth; R M Lucas; J Martinez-Abaigar; K McNeill; C M Olsen; K K Pandey; L E Rhodes; S A Robinson; K C Rose; T Schikowski; K R Solomon; B Sulzberger; J E Ukpebor; Q-W Wang; S-Å Wängberg; C C White; S Yazar; A R Young; P J Young; L Zhu; M Zhu Journal: Photochem Photobiol Sci Date: 2021-01-20 Impact factor: 4.328
Authors: Leonie Roos; Johanna K Sandling; Christopher G Bell; Daniel Glass; Massimo Mangino; Tim D Spector; Panos Deloukas; Veronique Bataille; Jordana T Bell Journal: J Invest Dermatol Date: 2016-12-18 Impact factor: 8.551
Authors: Brooke L Magnanti; M Tevfik Dorak; Louise Parker; Alan W Craft; Peter W James; Richard Jq McNally Journal: BMC Cancer Date: 2008-04-03 Impact factor: 4.430