Wang et al. / J Zhejiang Univ-Sci B (Biomed & Biotechnol) 2016 17(7):545-552 545 Vitamin D status among infants, children, and adolescents in southeastern China* Ling-li WANG1, Hui-yan WANG1, Huai-kai WEN1, Hong-qun TAO1, Xiao-wei ZHAO†‡2 (1Unit of Laboratory Medicine, Second Hospital Affiliated to Wenzhou Medical University, Wenzhou 325027, China) (2College of Life and Environmental Science, Wenzhou University, Wenzhou 325035, China) †E-mail: sherwood@wzu.edu.cn Received Nov. 19, 2015; Revision accepted Mar. 8, 2016; Crosschecked June 18, 2016 Abstract: Objective: Vitamin D deficiency and insufficiency are global public health problems, which must first be identified before they can be appropriately addressed, and yet information is strikingly lacking in most parts of the Asia and Pacific region. The study aimed to document and account for the actual situation in Wenzhou on the southeastern coast of China. Subjects and methods: Serum 25-hydroxyvitamin D levels among a total of 5845 infants, preschool children, school children, and adolescents aged 1–18 years were examined between March 2014 and February 2015. Results: Their mean levels were (110.2±26.8), (77.5±25.7), (55.6±15.4), and (47.2±13.9) nmol/L, respectively. Older age groups were involved in increasing risk of vitamin D deficiency and insufficiency. There were significant seasonal differences in its median level and prevalence of deficiency and insufficiency among school children and adolescents, but there was no significant sex difference in mean level and prevalence in any age group. Conclusions: Vitamin D deficiency and insufficiency were prevalent among infants, preschool children, school children, and adolescents in Wenzhou. A vitamin D-rich diet and outdoor activities for 1–2 h per day under the natural conditions favorable to its endogeous synthesis do not suffice. The vitamin D status in Wenzhounese infants excelling over that in the US was the result of its supplementation thanks to the Chinese Medical Association recommendations, which should be conse- quently extended to more age groups. Life style shaped by socio-economic environments affects vitamin D status. Knowledge on the importance of vitamin D for healthy growth should be popularized. Key words: Vitamin D, Deficiency, Child, China http://dx.doi.org/10.1631/jzus.B1500285 CLC number: R591.44 1 Introduction Increasing evidence suggests that vitamin D has multiple biological functions in addition to the clas- sical effects on calcium and phosphorus metabolism and on bone health and muscle strength. Vitamin D deficiency and insufficiency have been associated with non-skeletal diseases, such as depression, dia- betes, heart failure, high blood pressure, rheumatoid arthritis, selected cancers, schizophrenia, and tuber- culosis (Zittermann and Gummert, 2010; Schöttker et al., 2013). Although there is no consensus on the optimal vitamin D status, most specialists agree that its deficiency should be defined as serum 25-hydroxyvitamin D (25-OHD) levels at less than 50 nmol/L, insufficiency as levels between 50 and 75 nmol/L, and adequacy as levels at more than 75 nmol/L (Holick et al., 2011). The levels even higher than 100 or 150 nmol/L have been recommended based on epidemiologic data (Bischoff-Ferrari et al., 2006). Vitamin D status in an individual is dependent on genetic inheritance, lifestyle, and geographical conditions. Systematic reviews revealed that vitamin Journal of Zhejiang University-SCIENCE B (Biomedicine & Biotechnology) ISSN 1673-1581 (Print); ISSN 1862-1783 (Online) www.zju.edu.cn/jzus; www.springerlink.com E-mail: jzus@zju.edu.cn ‡ Corresponding author * Project supported by the Wenzhou Municipal Science and Technol- ogy Bureau Grant (No. Y20150313), China ORCID: Xiao-wei ZHAO, http://orcid.org/0000-0003-3315-3866 © Zhejiang University and Springer-Verlag Berlin Heidelberg 2016 Wang et al. / J Zhejiang Univ-Sci B (Biomed & Biotechnol) 2016 17(7):545-552 546 D deficiency and insufficiency are prevalent in all ethnicities and age groups where data are available around the globe, even in those living in areas with low latitude where a high level of solar ultraviolet B radiation initiates significant photochemical synthesis of vitamin D in human skin and those residing in advanced countries where vitamin D fortification has now been implemented for years (Wahl et al., 2012; Palacios and Gonzalez, 2014). For example, 72% of school children aged 7–12 years in Kuala Lumpur, Malaysia had serum 25-OHD levels indicative of vitamin D deficiency (Khor et al., 2011). Results from the US National Health and Nutrition Examination Survey indicated that prevalence of vitamin D defi- ciency or insufficiency in the 12- to 15-year-old US population was 31% or 79%, respectively (Ganji et al., 2012). The situation is, however, still uncertain be- cause information on 25-OHD levels, especially among infants, children, and adolescents, is strikingly lacking in various parts of the world including most of the Asia and Pacific region (Wahl et al., 2012; Pala- cios and Gonzalez, 2014). Wenzhou, literally meaning “temperate prefec- ture” in Chinese, is an affluent district on the south- eastern coast of China at latitude 28° N and its diet is full of sea fish, such as cod, herring, and mackerel. The question arises of what is the case in such a place which is provided with plenty of solar radiation and abounds in foodstuffs containing substantial amounts of vitamin D? The aim of this study was to document and account for the actual situation of healthy infants, children, and adolescents living in a middle subtrop- ical region where the natural conditions for cutaneous synthesis of vitamin D appear favorable and its die- tary intake seems ample. 2 Subjects and methods 2.1 Subjects and study design Subjects in this cross-sectional study were re- cruited from healthy clients no more than 18 years old who visited the Second Hospital (also named the Yuying Children’s Hospital) Affiliated to Wenzhou Medical University (China) for health examination between March 2014 and February 2015. They were proved in the examination to have no evidence of abnormal liver or renal function or other diagnosed medical conditions that might potentially interfere with vitamin D metabolism, and agreed to take part in the study and provided informed consent signed by themselves or their legal guardians after the purpose and detailed design of the study were explained to them. A total of 5845 eligible subjects were divided into 4 groups based on their ages: 0–12 months, 2– 6 years, 7–11 years, and 12–18 years, representing infancy, preschool childhood, school childhood, and adolescence, respectively. February through April was astronomically specified as spring, May through July as summer, August through October as fall, and November through January as winter. The age, sex and seasonal distributions are listed in Table 1. The study was approved by the Human Research Ethics Committee at our hospital and was in accordance with the principles laid down in the World Medical Asso- ciation Declaration of Helsinki. Height and weight were measured to the nearest 0.1 cm and 0.1 kg, respectively, with each subject clad only in light clothing. A questionnaire (Liu et al., 2003) based on the 7-d recall (Sallis et al., 1993) was used to assess subjects’ outdoor activities. They and/or their legal guardians were asked to recall the hours engaging in outdoor activities over the past week, and then average outdoor activity time per day was calculated. Dietary vitamin D intake was as- sessed using the 24-h dietary recall (Lytle et al., 1993). The food items consumed during the past 24 h were reported by subjects and/or their legal guardians for 3 d consecutively (2 weekdays and Saturday or Sun- day) including breakfast, lunch, supper, and between- meal snacks. Average dietary vitamin D intake per Table 1 Age, sex, and seasonal distributions of subjects Group Seasonal distribution Spring Summer Fall Winter Total Infant Boy Girl 69 48 21 211 133 78 216 131 85 131 60 71 627 372 255 Preschool child Boy Girl 325 223 102 772 514 258 675 440 235 508 300 208 2280 1477 803 School child Boy Girl 220 151 69 778 539 239 794 547 247 293 195 98 2085 1432 653 Adolescent Boy Girl 110 84 26 352 267 85 275 191 84 116 87 29 853 629 224 Total 724 2113 1960 1048 5845 Wang et al. / J Zhejiang Univ-Sci B (Biomed & Biotechnol) 2016 17(7):545-552 547 day was calculated using the Nutrition Calculator Version 2.65 (Chinese Center for Disease Control, Beijing, China). According to the above described definition, serum 25-OHD levels less than 50 nmol/L were classified as vitamin D deficiency, levels be- tween 50 and 75 nmol/L as insufficiency, and levels more than 75 nmol/L as adequacy. 2.2 Vitamin D measurement Venous samples were collected in the morning after an overnight fast except for infants. The level of 25-OHD was determined with an electrochemilumi- nescence binding assay on a Cobas e 601 Analyzer (Roche Diagnostics GmbH, Mannheim, Germany), whose intra- and inter-assay coefficients of variation were within 4% and 10%, respectively. A matched test kit was used, following the manufacturer’s procedure. 2.3 Statistical analyses Measurement results were expressed as mean± standard deviation (SD) or median (quartile range) depending on the data distribution. The Kolmogorov- Smirnov test was applied to determine if a dataset was normally distributed and the Levene test was used to determine if relevant datasets had equal variances. Accordingly, the Student’s t-test, Cochran-Cox test, chi-square test, Mann-Whitney U-test, Kruskal-Wallis H-test, or Nemenyi test was performed to compare serum 25-OHD levels, vitamin D statuses, dietary vitamin D intakes, and outdoor activity time. Signif- icance was set at P<0.05 except in the Kolmogorov- Smirnov and Levene tests, where the significance level was set at P<0.10. 3 Results Statistical description and inference of the re- sults from vitamin D measurement are listed in Tables 2 and 3. The mean serum 25-OHD level de- creased while the decrement lessened as age in- creased. Accordingly, the vitamin D deficiency and insufficiency became prevalent as children grew up. Nearly 40% of school children and over 50% of adolescents were vitamin D deficient, while vitamin D insufficiency occurred in more than 1 of every 3 preschool children, 2 school children, and 3 ado- lescents, respectively. Few adolescents had vitamin D adequacy. Only 50% of preschool children exceeded the threshold of 75 nmol/L. There was no significant difference in mean serum 25-OHD level or preva- lence of vitamin D deficiency or insufficiency be- tween boys and girls in any age group. Nor was there significant seasonal difference in median level or prevalence among infants and preschool children. For school children and adolescents, however, there were significant seasonal differences around the year, which were found only between spring and summer and between fall and winter. Physical characteristics and vitamin D intakes of subjects are listed in Table 4. Season had an effect on the outdoor activity time in any age group. The time in summer/fall was significantly longer than that in spring/winter, but season had no effect on the dietary vitamin D intake in any age group (data not shown). The much higher median intake for infants than for the other three age groups was due to vitamin D supplementation in accordance with the Chinese Table 2 Mean serum 25-OHD levels and vitamin D statuses among infants, children, and adolescents, and their sex differences Group 25-OHD (nmol/L) Vitamin D status (%) Mean±SD P Deficiency Insufficiency Adequacy Median (95% CI) P Median (95% CI) P Median (95% CI) P Infant 110.2±26.8 0.772 1.4 (0.5–2.3) 0.366 8.6 (6.4–10.8) 0.897 90.0 (87.7–92.3) 0.681 Boy Girl 110.4±25.9 109.8±27.9 1.1 (0.0–2.2) 2.0 (0.3–3.7) 8.6 (5.8–11.4) 8.6 (5.2–12.0) 90.3 (87.3–93.3) 89.4 (85.6–93.2) Preschool child 77.5±25.7 0.232 15.1 (13.6–16.6) 0.384 34.5 (32.5–36.5) 0.894 50.4 (48.3–52.5) 0.518 Boy Girl 76.7±26.4 78.9±26.6 15.6 (13.7–17.5) 14.2 (11.8–16.6) 34.5 (32.1–36.9) 34.5 (31.2–37.8) 49.9 (47.4–52.4) 51.3 (47.8–54.8) School child 55.6±15.4 0.196 38.1 (36.0–40.2) 0.142 51.6 (49.5–53.7) 0.225 10.3 (9.0–11.6) 0.687 Boy Girl 56.7±15.7 53.3±15.6 37.0 (34.5–39.5) 40.4 (36.6–44.2) 52.5 (49.9–55.1) 49.6 (45.8–53.4) 10.5 (8.9–12.1) 10.0 (7.7–12.3) Adolescent 47.2±13.9 0.213 54.6 (51.3–57.9) 0.259 38.9 (35.6–42.2) 0.062 6.5 (4.8–8.2) 0.165 Boy Girl 48.7±13.9 42.8±13.1 55.8 (51.9–59.7) 51.3 (44.8–57.8) 37.0 (33.2–40.8) 44.2 (37.7–50.7) 7.2 (5.2–9.2) 4.5 (1.8–7.2) Data are expressed as mean±standard deviation (SD) or median (95% confidence interval (CI)). 25-OHD: 25-hydroxyvitamin D Wang et al. / J Zhejiang Univ-Sci B (Biomed & Biotechnol) 2016 17(7):545-552 548 Medical Association (CMA) recommendation in 2008 that infants and toddlers from 2 weeks old to 2 years old receive 400 international units (IU) per day and another in 2009 that vitamin D-fortified food be fed to infants and toddlers aged from 0 to 3 years old. Almost all infants were supplemented with vit- amin D, but taking supplements was a lot less popular for the older preschool children, and especially the school children and more especially the adolescents. If vitamin D supplements were excluded, there was no significant difference in median intake among these three age groups (P=0.527). The intakes were derived mainly from sea fish (ca. 58%), egg (ca. 22%), and milk (ca. 15%), and would be ca. 102 IU. 4 Discussion Vitamin D deficiency and insufficiency are major global public health problems and must first be identified before they can be appropriately addressed. No national landscape of vitamin D status has been depicted in China, although the number of 25-OHD examinations in various populations, regions, and seasons has been escalating. Few investigations fo- cused on infants, children, or adolescents, and yet their results were alarmingly below the threshold of 50 nmol/L (Arguelles et al., 2009; Foo et al., 2009; Strand et al., 2009; Zhang et al., 2014) and built up the same picture as in other parts of the world (Zhang Table 3 Median serum 25-OHD levels and vitamin D statuses among infants, children, and adolescents, and their seasonal differences Group 25-OHD (nmol/L) Vitamin D status (%) Median (QR) P Deficiency Insufficiency Adequacy Median (95% CI) P Median (95% CI) P Median (95% CI) P Infant 110.2 (35.8) 0.519 1.4 (0.5–2.3) 0.700 8.6 (6.4–10.8) 0.065 90.0 (87.7–92.3) 0.069 Spring Summer Fall Winter 108.0 (38.9) 113.2 (37.1) 110.1 (30.3) 106.8 (34.6) 2.9 (0.0–6.9) 1.4 (0.0–3.0) 1.4 (0.0–3.0) 2.8 (0.0–2.3) 11.6 (4.0–19.2) 11.4 (7.1–15.7) 4.6 (1.8–7.4) 9.1 (4.2–14.0) 85.5 (77.2–93.8) 87.2 (82.7–91.7) 94.0 (90.8–97.2) 90.1 (8.50–95.2) Preschool child 75.2 (35.7) 0.120 15.1 (13.6–16.6) 0.767 34.5 (32.5–36.5) 0.104 50.4 (48.3–52.5) 0.235 Spring Summer Fall Winter 71.9 (39.4) 77.2 (37.0) 76.4 (33.1) 74.9 (37.8) 16.0 (12.0–20.0) 14.4 (11.9–16.9) 14.7 (12.0–17.4) 16.1 (12.9–19.3) 35.7 (30.5–40.9) 32.5 (29.2–35.8) 35.4 (31.8–39.0) 35.8 (31.6–40.0) 48.3 (42.9–53.7) 53.1 (49.6–56.6) 49.9 (46.1–53.7) 48.1 (43.8–52.4) School child 55.0 (20.8) 0.003 38.1 (36.0–40.2) 0.001 51.6 (49.5–53.7) 0.002 10.3 (9.0–11.6) 0.002 Spring* Summer** Fall* Winter** 50.1 (18.4) 56.9 (21.5) 58.4 (21.1) 52.1 (20.6) 53.6 (47.0–60.2) 35.1 (31.7–38.5) 32.9 (29.6–36.2) 48.8 (43.1–54.5) 41.8 (35.3–48.3) 52.2 (48.7–55.7) 55.9 (52.4–59.4) 45.7 (40.0–51.4) 4.6 (1.9–7.3) 12.7 (10.4–15.0) 11.2 (9.0–13.4) 5.5 (2.9–8.1) Adolescent 46.2 (19.0) 0.001 54.6 (51.3–57.9) 0.001 38.9 (35.6–42.2) 0.002 6.5 (4.8–8.2) 0.002 Spring* Summer** Fall* Winter** 41.3 (20.5) 50.7 (17.9) 49.2 (16.9) 40.2 (19.7) 73.6 (65.4–81.8) 51.4 (46.2–56.6) 44.0 (38.1–49.9) 71.6 (63.4–79.8) 26.4 (18.2–34.6) 41.5 (36.4–46.6) 45.8 (39.9–51.7) 26.7 (18.6–34.8) 0.0 (0.0–0.0) 7.1 (4.4–9.8) 10.2 (6.6–13.8) 1.7 (0.0–4.1) Data are expressed as median (quartile range (QR)) or median (95% confidence interval (CI)). 25-OHD: 25-hydroxyvitamin D. * Signifi- cantly different from next season but not significantly different from previous one; ** Significantly different from previous season but not significantly different from next one Table 4 Physical characteristics and vitamin D intakes of subjects Group Height (cm) Weight (kg) Outdoor activities (h/d) Vitamin D intake (IU/d)Boy Girl Boy Girl SP/WI SU/FA P Infant 70.1±4.4 67.3±3.1 8.8±2.1 7.6±1.8 0.96±0.18 1.09±0.20 <0.001 437 (49) Preschool child 100.7±4.0 99.5±3.7 15.9±1.9 15.4±1.9 1.83±0.24 2.02±0.26 <0.001 134 (28) School child 138.1±5.6 137.6±6.0 32.6±5.7 30.6±5.4 0.94±0.14 0.99±0.13 <0.001 123 (43) Adolescent 166.9±6.5 158.6±5.6 55.0±8.3 48.4±6.4 0.88±0.11 0.96±0.12 <0.001 119 (51) Data are expressed as mean±standard deviation (SD) or median (quartile range (QR)). SP: spring; WI: winter; SU: summer; FA: fall Wang et al. / J Zhejiang Univ-Sci B (Biomed & Biotechnol) 2016 17(7):545-552 549 et al., 2013). However, these previous researches were completed above latitude 30° N, with sample sizes being generally very small. Our investigation found that the dietary vitamin D intake for preschool children, school children, and adolescents in Wenzhou was mainly derived from sea fish and as the saying goes what we eat depends on what abounds in the place where we live, and that standing dishes full of sea fish all the year around provided substantial amounts of vitamin D, so season had no effect on the dietary vitamin D intake. How- ever, even such a diet was not enough to provide the daily allowance of 400 IU. The vitamin D intake exclusively from diet in these three age groups merely gave ca. 25% of the daily allowance, though it was much higher than those for adolescent girls in Beijing, China (Foo et al., 2009) and Greek preschool children (Nicolaidou et al., 2006), and on a par with that for British children aged 4–18 years (Absoud et al., 2011). Even with vitamin D supplementation included, it was much lower than the intake for American school children, whose prevalence of deficiency was 21% (Mansbach et al., 2009), compared to 38% in their Wenzhounese counterparts. Given that supplementa- tion of vitamin D is less and less popular as children grew up, it was no wonder that vitamin D deficiency and insufficiency were prevalent and older age groups were involved in increasing risk in Wenzhou. Even so the mean and median 25-OHD levels among adoles- cents in Wenzhou were lower than those in 1006 European counterparts participating in a Healthy Lifestyle in Europe by Nutrition in Adolescence cross-sectional study (Gonzàlez-Gross et al., 2012; Moreno et al., 2014). Meanwhile, only 6.5% of ado- lescents in Wenzhou were vitamin D sufficient, compared to 18.9% in the same European study (Gonzàlez-Gross et al., 2012). In sharp contrast, the vitamin D status in Wen- zhounese infants, who were well supplemented in accordance with the CMA recommendations, ex- celled over that in advanced countries. For example, the prevalence of vitamin D deficiency was 1.4% and 9.7% among Wenzhounese infants and American white infants (Bodnar et al., 2007), respectively. Therefore, we propose the CMA recommendations should be extended to older preschool children, school children, and adolescents, and even to all age groups. More intriguingly, comparison of the physical characteristics and vitamin D intakes between pre- school children and infants indicated that supple- mentation would be necessary for vitamin D status to be optimal even under the condition of outdoor ac- tivity time appropriate to the norm of 1–2 h per day recommended by the CMA. It meant that engagement in outdoor activities for 1–2 h per day did not suffice or the seemingly favorable geographical conditions did not guarantee endogenous synthesis of vitamin D as a result of skin exposure to solar ultraviolet B ra- diation. Further studies, however, will be needed to clarify this issue because investigation into actual solar ultraviolet B radiation and subjects’ skin expo- sure to sunlight was not included in our questionnaire. It would be conducive to displaying the vitamin D status on the southeastern coast of China to com- pare our study with an investigation conducted in Hangzhou (Zhu et al., 2012), not only because both Wenzhou and Hangzhou belong to Zhejiang Province and their people have similar lifestyle, but also be- cause the two districts are distinct in many aspects. Hangzhou, the provincial capital, features a typical Wu culture, a branch of mainstream Chinese culture. Wenzhou, at the southernmost 2° latitude apart, has more cultural and physical-anthropological traits originating from farther southern China. According to the comparison (data not shown), the mean serum 25-OHD levels among infants and preschool children in Wenzhou were significantly higher than those in Hangzhou, whereas the levels among girl school children and among all or boy or girl adolescents in Wenzhou were significantly lower than those among their counterparts in Hangzhou. Both Wenzhou and Hangzhou are affluent, and the Only Child policy in China makes parents eager to offer nutritious food to their babies. The data collec- tion in Hangzhou took place between March 2008 and February 2011. We took samples between March 2014 and February 2015. During the intervening pe- riod of the studies, the awareness and concern that vitamin D deficiency and insufficiency are common and place children at high risk for chronic diseases had been growing in parents’ minds thanks to the CMA recommendations for vitamin D supplementa- tion. Meanwhile, vitamin D-fortified supplements had become easily accessible. The higher serum 25-OHD levels among infants and preschool children Wang et al. / J Zhejiang Univ-Sci B (Biomed & Biotechnol) 2016 17(7):545-552 550 in Wenzhou than those in Hangzhou can therefore be a result of the rapid developments in China over the past decade. Affluent though both districts are, the social in- frastructure in newly developed Wenzhou still lags behind that in Hangzhou which has advanced for centuries and has been reputed as a paradise on Earth. As far as middle school students are concerned, ad- mission to college from Wenzhou is more difficult than that from Hangzhou due to the relatively poorer quality of education. Students in Wenzhou conse- quently have to bear heavier burdens of classroom work in order to make up for this—getting into col- lege is a long, frenzied, and competitive process in China. So they have less time playing outdoors and receiving solar radiation with a resulting poorer vit- amin D status. This was supported by the statistical results from physical examination of college freshmen/ women in Zhejiang Province, with those from Hangzhou being the most healthy and those from Wenzhou the least (Zhejiang Provincial Department of Education, 2014). Thus, it is critical to infuse knowledge on the importance of vitamin D for healthy growth into the hearts of educators and edu- catees. As the saying of American philosopher and writer Ralph Waldo EMERSON goes, the first wealth is health! Ancestors of the Wenzhounese mainly came from farther southern China. Although their genetic origins are diversified today and human skin color is affected by many substances, Wenzhounese are gen- erally described as tan skinned compared to the northerners such as Hangzhounese just as dark skin is more often mentioned for the southerners (Eberhard, 1965). Fair skin is a very long-honed determinant of beauty and regarded as a sign of high socio-economic class in virtually mono-racial China. Girls in Wen- zhou confess themselves beige pigmented, so they are more especially deeply indulged in light skin so that they avoid voluntary sun exposure. As they grow up and become fashion conscious, they hide beneath umbrellas, stay covered in clothes, or use sunscreens when going outside to keep the sun from ‘disfiguring’ their complexions. These behaviors may explain in part the finding that the mean serum 25-OHD levels among older girls in Wenzhou were significantly lower than those among their counterparts in Hang- zhou. Only when adverse outcomes of vitamin D deficiency and insufficiency are recognized, will this neurosis and these induced behaviors harmful to healthy growth be changed. Additionally, the significant seasonal differences in median serum 25-OHD level and prevalence of vitamin D deficiency and insufficiency were found in Wenzhou only between spring and summer and be- tween fall and winter. By contrast, those in Hangzhou were also present between spring and winter. Based on theoretical calculation, Wenzhou and Hangzhou receive almost equal amounts of solar ultraviolet B irradiances quarterly. In the past 50 years, however, there was average temperature difference of 4 °C in winter between Wenzhou (8–16 °C) and Hangzhou (4–12 °C) because of obstruction by mountains, while nearly zero temperature difference during other sea- sons (9–16 °C verse 7–15 °C in spring, 22–28 °C verse 21–29 °C in summer, and 21–29 °C verse 20– 28 °C in fall); furthermore, winter in Wenzhou lasted 25 d fewer than that in Hangzhou (Yang and Mao, 2008). Shorter duration and warmer temperature made winter in Wenzhou almost identical to its spring meteorologically, thus there was no seasonal differ- ence between the two seasons. 5 Conclusions This cross-sectional study showed that vitamin D deficiency and insufficiency were prevalent among infants, preschool children, school children, and ad- olescents in Wenzhou and became more severe as children grew up. There was no significant sex dif- ference in mean serum 25-OHD level or prevalence of vitamin D deficiency and insufficiency in any age group, but there were significant seasonal differences in median level and prevalence among school chil- dren and adolescents, although the samples in our study were recruited from the health examinees rather than from the entire pediatric population. This is in- deed a defect of the study but the big sample size is a remedy for representativeness. Lifestyle shaped by socio-economic environments affects vitamin D sta- tus. A diet full of sea fish provided a substantial amount of vitamin D all the year around, and yet it was not enough to give the daily allowance. Sup- plementation would be necessary even when outdoor activities for 1–2 h per day were guaranteed, though Wang et al. / J Zhejiang Univ-Sci B (Biomed & Biotechnol) 2016 17(7):545-552 551 the natural conditions seem favorable to cutaneous synthesis of vitamin D. 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Nutrients, 2(4):408-425. http://dx.doi.org/10.3390/nu2040408 中文概要 题 目:中国东南地区婴儿、儿童与少年的维生素 D 状态 目 的:维生素 D 缺乏和不足是全球性的公共卫生问题, 欲妥善解决,必首先了解之。 创新点:大部分亚太地区关于维生素 D 状态的信息奇缺, 本研究记录与分析了地处中国东南沿海的温州 的实际状况。 方 法:2014 年 3 月至 2015 年 2 月之间,总共检测了 5845 名年龄在 1~18 岁的婴儿、学前儿童、学龄儿童 与少年的血清 25-羟基维生素 D 水平。其均数分 别为(110.2±26.8)、(77.5±25.7)、(55.6±15.4) 与(47.2±13.9)nmol/L。随着年龄增大,发生维 生素 D 缺乏和不足的风险升高。学龄儿童与少年 的中位数与维生素 D 缺乏和不足发生率存在显 著的季节差异,而所有年龄段的均数与发生率不 存在显著的性别差异。 结 论:维生素 D 缺乏和不足普遍发生于温州的婴儿、学 前儿童、学龄儿童与少年,富含维生素 D 的饮食 与在有利于维生素 D 内源性合成的自然条件下 每天户外活动 1~2 小时并不能满足需求。温州婴 儿的维生素 D 状态优于美国婴儿,是因为中国医 学会自 2008 年以来推荐 2 周至 2 岁的婴幼儿应 每天摄入 400 IU 维生素 D,自 2009 年以来推荐 3 岁以下的婴幼儿应喂食维生素 D 强化食物,因 此,其推荐范围应当扩展至更多年龄段。因社会 经济环境形成的生活方式影响维生素 D 状态,应 当广泛宣传关于维生素 D 对于健康生长至关重 要的知识。 关键词:维生素 D;缺乏;儿童;中国