Effect of iodine intake on serum thyroglobulin——A five-year prospective epidemiological study

Objective To clarify the effect of iodine intake on serum thyroglobulin (Tg). Methods A 5-year prospective study was conducted in the 3 different iodine intake areas in China [Panshan (miht deficiency) ,Zhangwu (more than adequate) and Huanghua (excess)]. A total of 3 099 people with normal serum levels of Tg in 1999 were followed and 2 448 of these participants were feasible to be observed in 2004 and included in the present study. The serum levels of Tg, thyraglobulin antibody(TgAb), thyroid peroxidase antibody(TPOAb) and TSH, thyroid volume, family and personal histories of thyroid diseases were measured and inquried. The general linear model (GLM) was used to explore the determinants of Tg. Results Among the study population at baseline, serum Tg were significantly different in three areas [7.5 (4.4-13. 1) μg/L at Panshan, 6.8 (3.6-11.2)μg/L at Huanghua, 5.9 (3.2-10.7) μg/L at Zhangwu, P<0.01]. They were associated with age, sex and the rate of positive TgAb, abnormal thyroid volume, abnormal TSH and positive personal history of thyroid diseases, in order to control the effects of confounding factors, the data from 1856 subjects with thyroid-related indexes all in normal range and without personal history of thyroid diseases were analyzed to clarify the effect of iodine intake on Tg. The serum Tg among three areas were significantly different in both 1999 and 2004, they were all increased in 5 years with significant augment (△ Tg) among the three areas[3.1 (-0.2-8.0) μg/L at Panshan, 3.5 (0.5-9.0)μg/L at Huanghua vs 2. 5(0.3-6.1) μg/L at Zhangwu,P<0.01]. The GLM analysis revealed that age, Tg and TSH levels at baseline were the determinants of △Tg in addition to iodine intake. Conclusion Iodine intake is a dominant determinant of serum Tg. Age and TSH should also be considered while indicating iodine intake by serum Tg.     

Effect of iodine intake on serum thyroglobulin——A five-year prospective epidemiological study

Objective To clarify the effect of iodine intake on serum thyroglobulin (Tg). Methods A 5-year prospective study was conducted in the 3 different iodine intake areas in China [Panshan (miht deficiency) ,Zhangwu (more than adequate) and Huanghua (excess)]. A total of 3 099 people with normal serum levels of Tg in 1999 were followed and 2 448 of these participants were feasible to be observed in 2004 and included in the present study. The serum levels of Tg, thyraglobulin antibody(TgAb), thyroid peroxidase antibody(TPOAb) and TSH, thyroid volume, family and personal histories of thyroid diseases were measured and inquried. The general linear model (GLM) was used to explore the determinants of Tg. Results Among the study population at baseline, serum Tg were significantly different in three areas [7.5 (4.4-13. 1) μg/L at Panshan, 6.8 (3.6-11.2)μg/L at Huanghua, 5.9 (3.2-10.7) μg/L at Zhangwu, P<0.01]. They were associated with age, sex and the rate of positive TgAb, abnormal thyroid volume, abnormal TSH and positive personal history of thyroid diseases, in order to control the effects of confounding factors, the data from 1856 subjects with thyroid-related indexes all in normal range and without personal history of thyroid diseases were analyzed to clarify the effect of iodine intake on Tg. The serum Tg among three areas were significantly different in both 1999 and 2004, they were all increased in 5 years with significant augment (△ Tg) among the three areas[3.1 (-0.2-8.0) μg/L at Panshan, 3.5 (0.5-9.0)μg/L at Huanghua vs 2. 5(0.3-6.1) μg/L at Zhangwu,P<0.01]. The GLM analysis revealed that age, Tg and TSH levels at baseline were the determinants of △Tg in addition to iodine intake. Conclusion Iodine intake is a dominant determinant of serum Tg. Age and TSH should also be considered while indicating iodine intake by serum Tg.     

Effect of iodine intake on serum thyroglobulin——A five-year prospective epidemiological study

Objective To clarify the effect of iodine intake on serum thyroglobulin (Tg). Methods A 5-year prospective study was conducted in the 3 different iodine intake areas in China [Panshan (miht deficiency) ,Zhangwu (more than adequate) and Huanghua (excess)]. A total of 3 099 people with normal serum levels of Tg in 1999 were followed and 2 448 of these participants were feasible to be observed in 2004 and included in the present study. The serum levels of Tg, thyraglobulin antibody(TgAb), thyroid peroxidase antibody(TPOAb) and TSH, thyroid volume, family and personal histories of thyroid diseases were measured and inquried. The general linear model (GLM) was used to explore the determinants of Tg. Results Among the study population at baseline, serum Tg were significantly different in three areas [7.5 (4.4-13. 1) μg/L at Panshan, 6.8 (3.6-11.2)μg/L at Huanghua, 5.9 (3.2-10.7) μg/L at Zhangwu, P<0.01]. They were associated with age, sex and the rate of positive TgAb, abnormal thyroid volume, abnormal TSH and positive personal history of thyroid diseases, in order to control the effects of confounding factors, the data from 1856 subjects with thyroid-related indexes all in normal range and without personal history of thyroid diseases were analyzed to clarify the effect of iodine intake on Tg. The serum Tg among three areas were significantly different in both 1999 and 2004, they were all increased in 5 years with significant augment (△ Tg) among the three areas[3.1 (-0.2-8.0) μg/L at Panshan, 3.5 (0.5-9.0)μg/L at Huanghua vs 2. 5(0.3-6.1) μg/L at Zhangwu,P<0.01]. The GLM analysis revealed that age, Tg and TSH levels at baseline were the determinants of △Tg in addition to iodine intake. Conclusion Iodine intake is a dominant determinant of serum Tg. Age and TSH should also be considered while indicating iodine intake by serum Tg.     

Effect of iodine intake on serum thyroglobulin——A five-year prospective epidemiological study

Objective To clarify the effect of iodine intake on serum thyroglobulin (Tg). Methods A 5-year prospective study was conducted in the 3 different iodine intake areas in China [Panshan (miht deficiency) ,Zhangwu (more than adequate) and Huanghua (excess)]. A total of 3 099 people with normal serum levels of Tg in 1999 were followed and 2 448 of these participants were feasible to be observed in 2004 and included in the present study. The serum levels of Tg, thyraglobulin antibody(TgAb), thyroid peroxidase antibody(TPOAb) and TSH, thyroid volume, family and personal histories of thyroid diseases were measured and inquried. The general linear model (GLM) was used to explore the determinants of Tg. Results Among the study population at baseline, serum Tg were significantly different in three areas [7.5 (4.4-13. 1) μg/L at Panshan, 6.8 (3.6-11.2)μg/L at Huanghua, 5.9 (3.2-10.7) μg/L at Zhangwu, P<0.01]. They were associated with age, sex and the rate of positive TgAb, abnormal thyroid volume, abnormal TSH and positive personal history of thyroid diseases, in order to control the effects of confounding factors, the data from 1856 subjects with thyroid-related indexes all in normal range and without personal history of thyroid diseases were analyzed to clarify the effect of iodine intake on Tg. The serum Tg among three areas were significantly different in both 1999 and 2004, they were all increased in 5 years with significant augment (△ Tg) among the three areas[3.1 (-0.2-8.0) μg/L at Panshan, 3.5 (0.5-9.0)μg/L at Huanghua vs 2. 5(0.3-6.1) μg/L at Zhangwu,P<0.01]. The GLM analysis revealed that age, Tg and TSH levels at baseline were the determinants of △Tg in addition to iodine intake. Conclusion Iodine intake is a dominant determinant of serum Tg. Age and TSH should also be considered while indicating iodine intake by serum Tg.     

Effect of iodine intake on serum thyroglobulin——A five-year prospective epidemiological study

Objective To clarify the effect of iodine intake on serum thyroglobulin (Tg). Methods A 5-year prospective study was conducted in the 3 different iodine intake areas in China [Panshan (miht deficiency) ,Zhangwu (more than adequate) and Huanghua (excess)]. A total of 3 099 people with normal serum levels of Tg in 1999 were followed and 2 448 of these participants were feasible to be observed in 2004 and included in the present study. The serum levels of Tg, thyraglobulin antibody(TgAb), thyroid peroxidase antibody(TPOAb) and TSH, thyroid volume, family and personal histories of thyroid diseases were measured and inquried. The general linear model (GLM) was used to explore the determinants of Tg. Results Among the study population at baseline, serum Tg were significantly different in three areas [7.5 (4.4-13. 1) μg/L at Panshan, 6.8 (3.6-11.2)μg/L at Huanghua, 5.9 (3.2-10.7) μg/L at Zhangwu, P<0.01]. They were associated with age, sex and the rate of positive TgAb, abnormal thyroid volume, abnormal TSH and positive personal history of thyroid diseases, in order to control the effects of confounding factors, the data from 1856 subjects with thyroid-related indexes all in normal range and without personal history of thyroid diseases were analyzed to clarify the effect of iodine intake on Tg. The serum Tg among three areas were significantly different in both 1999 and 2004, they were all increased in 5 years with significant augment (△ Tg) among the three areas[3.1 (-0.2-8.0) μg/L at Panshan, 3.5 (0.5-9.0)μg/L at Huanghua vs 2. 5(0.3-6.1) μg/L at Zhangwu,P<0.01]. The GLM analysis revealed that age, Tg and TSH levels at baseline were the determinants of △Tg in addition to iodine intake. Conclusion Iodine intake is a dominant determinant of serum Tg. Age and TSH should also be considered while indicating iodine intake by serum Tg.     

Effect of iodine intake on serum thyroglobulin——A five-year prospective epidemiological study

Objective To clarify the effect of iodine intake on serum thyroglobulin (Tg). Methods A 5-year prospective study was conducted in the 3 different iodine intake areas in China [Panshan (miht deficiency) ,Zhangwu (more than adequate) and Huanghua (excess)]. A total of 3 099 people with normal serum levels of Tg in 1999 were followed and 2 448 of these participants were feasible to be observed in 2004 and included in the present study. The serum levels of Tg, thyraglobulin antibody(TgAb), thyroid peroxidase antibody(TPOAb) and TSH, thyroid volume, family and personal histories of thyroid diseases were measured and inquried. The general linear model (GLM) was used to explore the determinants of Tg. Results Among the study population at baseline, serum Tg were significantly different in three areas [7.5 (4.4-13. 1) μg/L at Panshan, 6.8 (3.6-11.2)μg/L at Huanghua, 5.9 (3.2-10.7) μg/L at Zhangwu, P<0.01]. They were associated with age, sex and the rate of positive TgAb, abnormal thyroid volume, abnormal TSH and positive personal history of thyroid diseases, in order to control the effects of confounding factors, the data from 1856 subjects with thyroid-related indexes all in normal range and without personal history of thyroid diseases were analyzed to clarify the effect of iodine intake on Tg. The serum Tg among three areas were significantly different in both 1999 and 2004, they were all increased in 5 years with significant augment (△ Tg) among the three areas[3.1 (-0.2-8.0) μg/L at Panshan, 3.5 (0.5-9.0)μg/L at Huanghua vs 2. 5(0.3-6.1) μg/L at Zhangwu,P<0.01]. The GLM analysis revealed that age, Tg and TSH levels at baseline were the determinants of △Tg in addition to iodine intake. Conclusion Iodine intake is a dominant determinant of serum Tg. Age and TSH should also be considered while indicating iodine intake by serum Tg.     

Effect of iodine intake on serum thyroglobulin——A five-year prospective epidemiological study

Objective To clarify the effect of iodine intake on serum thyroglobulin (Tg). Methods A 5-year prospective study was conducted in the 3 different iodine intake areas in China [Panshan (miht deficiency) ,Zhangwu (more than adequate) and Huanghua (excess)]. A total of 3 099 people with normal serum levels of Tg in 1999 were followed and 2 448 of these participants were feasible to be observed in 2004 and included in the present study. The serum levels of Tg, thyraglobulin antibody(TgAb), thyroid peroxidase antibody(TPOAb) and TSH, thyroid volume, family and personal histories of thyroid diseases were measured and inquried. The general linear model (GLM) was used to explore the determinants of Tg. Results Among the study population at baseline, serum Tg were significantly different in three areas [7.5 (4.4-13. 1) μg/L at Panshan, 6.8 (3.6-11.2)μg/L at Huanghua, 5.9 (3.2-10.7) μg/L at Zhangwu, P<0.01]. They were associated with age, sex and the rate of positive TgAb, abnormal thyroid volume, abnormal TSH and positive personal history of thyroid diseases, in order to control the effects of confounding factors, the data from 1856 subjects with thyroid-related indexes all in normal range and without personal history of thyroid diseases were analyzed to clarify the effect of iodine intake on Tg. The serum Tg among three areas were significantly different in both 1999 and 2004, they were all increased in 5 years with significant augment (△ Tg) among the three areas[3.1 (-0.2-8.0) μg/L at Panshan, 3.5 (0.5-9.0)μg/L at Huanghua vs 2. 5(0.3-6.1) μg/L at Zhangwu,P<0.01]. The GLM analysis revealed that age, Tg and TSH levels at baseline were the determinants of △Tg in addition to iodine intake. Conclusion Iodine intake is a dominant determinant of serum Tg. Age and TSH should also be considered while indicating iodine intake by serum Tg.     

Effect of iodine intake on serum thyroglobulin——A five-year prospective epidemiological study

Objective To clarify the effect of iodine intake on serum thyroglobulin (Tg). Methods A 5-year prospective study was conducted in the 3 different iodine intake areas in China [Panshan (miht deficiency) ,Zhangwu (more than adequate) and Huanghua (excess)]. A total of 3 099 people with normal serum levels of Tg in 1999 were followed and 2 448 of these participants were feasible to be observed in 2004 and included in the present study. The serum levels of Tg, thyraglobulin antibody(TgAb), thyroid peroxidase antibody(TPOAb) and TSH, thyroid volume, family and personal histories of thyroid diseases were measured and inquried. The general linear model (GLM) was used to explore the determinants of Tg. Results Among the study population at baseline, serum Tg were significantly different in three areas [7.5 (4.4-13. 1) μg/L at Panshan, 6.8 (3.6-11.2)μg/L at Huanghua, 5.9 (3.2-10.7) μg/L at Zhangwu, P<0.01]. They were associated with age, sex and the rate of positive TgAb, abnormal thyroid volume, abnormal TSH and positive personal history of thyroid diseases, in order to control the effects of confounding factors, the data from 1856 subjects with thyroid-related indexes all in normal range and without personal history of thyroid diseases were analyzed to clarify the effect of iodine intake on Tg. The serum Tg among three areas were significantly different in both 1999 and 2004, they were all increased in 5 years with significant augment (△ Tg) among the three areas[3.1 (-0.2-8.0) μg/L at Panshan, 3.5 (0.5-9.0)μg/L at Huanghua vs 2. 5(0.3-6.1) μg/L at Zhangwu,P<0.01]. The GLM analysis revealed that age, Tg and TSH levels at baseline were the determinants of △Tg in addition to iodine intake. Conclusion Iodine intake is a dominant determinant of serum Tg. Age and TSH should also be considered while indicating iodine intake by serum Tg.     

Effect of iodine intake on serum thyroglobulin——A five-year prospective epidemiological study

Objective To clarify the effect of iodine intake on serum thyroglobulin (Tg). Methods A 5-year prospective study was conducted in the 3 different iodine intake areas in China [Panshan (miht deficiency) ,Zhangwu (more than adequate) and Huanghua (excess)]. A total of 3 099 people with normal serum levels of Tg in 1999 were followed and 2 448 of these participants were feasible to be observed in 2004 and included in the present study. The serum levels of Tg, thyraglobulin antibody(TgAb), thyroid peroxidase antibody(TPOAb) and TSH, thyroid volume, family and personal histories of thyroid diseases were measured and inquried. The general linear model (GLM) was used to explore the determinants of Tg. Results Among the study population at baseline, serum Tg were significantly different in three areas [7.5 (4.4-13. 1) μg/L at Panshan, 6.8 (3.6-11.2)μg/L at Huanghua, 5.9 (3.2-10.7) μg/L at Zhangwu, P<0.01]. They were associated with age, sex and the rate of positive TgAb, abnormal thyroid volume, abnormal TSH and positive personal history of thyroid diseases, in order to control the effects of confounding factors, the data from 1856 subjects with thyroid-related indexes all in normal range and without personal history of thyroid diseases were analyzed to clarify the effect of iodine intake on Tg. The serum Tg among three areas were significantly different in both 1999 and 2004, they were all increased in 5 years with significant augment (△ Tg) among the three areas[3.1 (-0.2-8.0) μg/L at Panshan, 3.5 (0.5-9.0)μg/L at Huanghua vs 2. 5(0.3-6.1) μg/L at Zhangwu,P<0.01]. The GLM analysis revealed that age, Tg and TSH levels at baseline were the determinants of △Tg in addition to iodine intake. Conclusion Iodine intake is a dominant determinant of serum Tg. Age and TSH should also be considered while indicating iodine intake by serum Tg.     

碘摄入量对血清甲状腺球蛋白的影响——5年流行病学随访研究

目的 观察碘摄入量对血清甲状腺球蛋白(Tg)水平的影响.方法 对1999年盘山(轻度碘缺乏地区)、彰武(碘超足量地区)和黄骅(碘过量地区)血清Tg水平正常的3 099人进行随访,将2004年随访到的2 448人作为研究人群.测定Tg、甲状腺球蛋白抗体(TgAb)、甲状腺过氧化物酶抗体(TPOAb)、促甲状腺素(TSH)、甲状腺容积,并询问甲状腺疾病的家族史和个人史.分析Tg的影响因素.结果 1999年初访时,不同碘摄入地区Tg水平差异显著[盘山7.5(4.4～13.1)μg/L、黄骅6.8(3.6～11.2)μg/L彰武5.9(3.2～10.7)μg/L,P<0.01];年龄、性别、TgAb阳性、甲状腺肿大、TSH异< 凹鬃聪偌膊「鋈耸范訲g水平的影响亦显著.为排除混杂因素的影响,对TgAb、甲状腺容积、TSH、甲状腺疾病个人史均无异常的1 856人的随访数据进行分析,其初访及随访的Tg水平均有显著地区差异,轻度碘缺乏以及碘过量地区都显著高于碘超足量地区.三地区随访时Tg水平均显著升高,且增加值(△Tg)存在显著地区差异[盘山3.1(-0.2～8.0)μg/L、黄骅3.5(0.5～9.0)μg/L/35彰武2.5(0.3～6.1)μg/L,P<0.01];碘摄入量、初访时的Tg水平、TSH水平及年龄为ATg的独立影响因素.结论 碘摄入量显著影响血清Tg水平,当用血清Tg水平来估计地区碘摄入水平及其变化时,应该同时考虑年龄及TSH等因素.     

不同碘摄入量对甲状腺肿和甲状腺结节影响的前瞻性研究

目的 研究不同碘摄入量人群非毒性甲状腺肿(甲肿)和非毒性甲状腺结节的流行病学特点及影响其发生、发展和转归的因素.方法 2004年对盘山(长期轻度碘缺乏)、彰武(碘缺乏基础上补碘至碘超足量)和黄骅(长期碘过量)社区于1999年参加本课题组流行病学研究并进行甲状腺B超检查的人群(3 385人)进行甲状腺疾病的随访调查.结果 (1)盘山、彰武和黄骅社区弥漫型甲肿的累积发病率分别为7.1%、4.4%和6.9%,盘山和黄骅均显著高于彰武(均P<0.01);结节型甲肿的累积发病率分别为5,0%、2.4%和0.8%,盘山的发病率最高(P<0.01).(2)三社区甲状腺单发结节的累积发病率分别为4.0%、5.7%和5.6%,多发结节的累积发病率分别为0.4%、1.2%和1.0%.(3)基础碘缺乏、碘过量、甲状腺自身抗体(thyroid autoantibody,TAA)阳性是甲肿发生的独立危险因素.(4)彰武初访时TAA阳性人群非毒性甲肿的发生率显著高于TAA阴性人群(P<0.01),盘山和黄骅无显著差异.(5)三社区非毒性弥漫型甲肿维持人群和黄骅非毒性结节型甲肿维持人群随访前后TAA阳性率均高于同社区正常人群(P<0.05).结论 碘缺乏和碘过量均有可能使甲肿的发病率增加.碘缺乏社区结节型甲肿高发,弥漫型甲肿是碘过量社区甲肿发牛的主要形式.甲状腺自身免疫与甲肿的发生和维持相关,这种相关性在历史上为碘缺乏而后过度补碘的社区更明显.     

不同碘摄入量对甲状腺肿和甲状腺结节影响的前瞻性研究

目的 研究不同碘摄入量人群非毒性甲状腺肿(甲肿)和非毒性甲状腺结节的流行病学特点及影响其发生、发展和转归的因素.方法 2004年对盘山(长期轻度碘缺乏)、彰武(碘缺乏基础上补碘至碘超足量)和黄骅(长期碘过量)社区于1999年参加本课题组流行病学研究并进行甲状腺B超检查的人群(3 385人)进行甲状腺疾病的随访调查.结果 (1)盘山、彰武和黄骅社区弥漫型甲肿的累积发病率分别为7.1%、4.4%和6.9%,盘山和黄骅均显著高于彰武(均P<0.01);结节型甲肿的累积发病率分别为5,0%、2.4%和0.8%,盘山的发病率最高(P<0.01).(2)三社区甲状腺单发结节的累积发病率分别为4.0%、5.7%和5.6%,多发结节的累积发病率分别为0.4%、1.2%和1.0%.(3)基础碘缺乏、碘过量、甲状腺自身抗体(thyroid autoantibody,TAA)阳性是甲肿发生的独立危险因素.(4)彰武初访时TAA阳性人群非毒性甲肿的发生率显著高于TAA阴性人群(P<0.01),盘山和黄骅无显著差异.(5)三社区非毒性弥漫型甲肿维持人群和黄骅非毒性结节型甲肿维持人群随访前后TAA阳性率均高于同社区正常人群(P<0.05).结论 碘缺乏和碘过量均有可能使甲肿的发病率增加.碘缺乏社区结节型甲肿高发,弥漫型甲肿是碘过量社区甲肿发牛的主要形式.甲状腺自身免疫与甲肿的发生和维持相关,这种相关性在历史上为碘缺乏而后过度补碘的社区更明显.     

不同碘摄入量对甲状腺肿和甲状腺结节影响的前瞻性研究

目的 研究不同碘摄入量人群非毒性甲状腺肿(甲肿)和非毒性甲状腺结节的流行病学特点及影响其发生、发展和转归的因素.方法 2004年对盘山(长期轻度碘缺乏)、彰武(碘缺乏基础上补碘至碘超足量)和黄骅(长期碘过量)社区于1999年参加本课题组流行病学研究并进行甲状腺B超检查的人群(3 385人)进行甲状腺疾病的随访调查.结果 (1)盘山、彰武和黄骅社区弥漫型甲肿的累积发病率分别为7.1%、4.4%和6.9%,盘山和黄骅均显著高于彰武(均P<0.01);结节型甲肿的累积发病率分别为5,0%、2.4%和0.8%,盘山的发病率最高(P<0.01).(2)三社区甲状腺单发结节的累积发病率分别为4.0%、5.7%和5.6%,多发结节的累积发病率分别为0.4%、1.2%和1.0%.(3)基础碘缺乏、碘过量、甲状腺自身抗体(thyroid autoantibody,TAA)阳性是甲肿发生的独立危险因素.(4)彰武初访时TAA阳性人群非毒性甲肿的发生率显著高于TAA阴性人群(P<0.01),盘山和黄骅无显著差异.(5)三社区非毒性弥漫型甲肿维持人群和黄骅非毒性结节型甲肿维持人群随访前后TAA阳性率均高于同社区正常人群(P<0.05).结论 碘缺乏和碘过量均有可能使甲肿的发病率增加.碘缺乏社区结节型甲肿高发,弥漫型甲肿是碘过量社区甲肿发牛的主要形式.甲状腺自身免疫与甲肿的发生和维持相关,这种相关性在历史上为碘缺乏而后过度补碘的社区更明显.     

不同碘摄入量对甲状腺肿和甲状腺结节影响的前瞻性研究

目的 研究不同碘摄入量人群非毒性甲状腺肿(甲肿)和非毒性甲状腺结节的流行病学特点及影响其发生、发展和转归的因素.方法 2004年对盘山(长期轻度碘缺乏)、彰武(碘缺乏基础上补碘至碘超足量)和黄骅(长期碘过量)社区于1999年参加本课题组流行病学研究并进行甲状腺B超检查的人群(3 385人)进行甲状腺疾病的随访调查.结果 (1)盘山、彰武和黄骅社区弥漫型甲肿的累积发病率分别为7.1%、4.4%和6.9%,盘山和黄骅均显著高于彰武(均P<0.01);结节型甲肿的累积发病率分别为5,0%、2.4%和0.8%,盘山的发病率最高(P<0.01).(2)三社区甲状腺单发结节的累积发病率分别为4.0%、5.7%和5.6%,多发结节的累积发病率分别为0.4%、1.2%和1.0%.(3)基础碘缺乏、碘过量、甲状腺自身抗体(thyroid autoantibody,TAA)阳性是甲肿发生的独立危险因素.(4)彰武初访时TAA阳性人群非毒性甲肿的发生率显著高于TAA阴性人群(P<0.01),盘山和黄骅无显著差异.(5)三社区非毒性弥漫型甲肿维持人群和黄骅非毒性结节型甲肿维持人群随访前后TAA阳性率均高于同社区正常人群(P<0.05).结论 碘缺乏和碘过量均有可能使甲肿的发病率增加.碘缺乏社区结节型甲肿高发,弥漫型甲肿是碘过量社区甲肿发牛的主要形式.甲状腺自身免疫与甲肿的发生和维持相关,这种相关性在历史上为碘缺乏而后过度补碘的社区更明显.     

不同碘摄入量对甲状腺肿和甲状腺结节影响的前瞻性研究

目的 研究不同碘摄入量人群非毒性甲状腺肿(甲肿)和非毒性甲状腺结节的流行病学特点及影响其发生、发展和转归的因素.方法 2004年对盘山(长期轻度碘缺乏)、彰武(碘缺乏基础上补碘至碘超足量)和黄骅(长期碘过量)社区于1999年参加本课题组流行病学研究并进行甲状腺B超检查的人群(3 385人)进行甲状腺疾病的随访调查.结果 (1)盘山、彰武和黄骅社区弥漫型甲肿的累积发病率分别为7.1%、4.4%和6.9%,盘山和黄骅均显著高于彰武(均P<0.01);结节型甲肿的累积发病率分别为5,0%、2.4%和0.8%,盘山的发病率最高(P<0.01).(2)三社区甲状腺单发结节的累积发病率分别为4.0%、5.7%和5.6%,多发结节的累积发病率分别为0.4%、1.2%和1.0%.(3)基础碘缺乏、碘过量、甲状腺自身抗体(thyroid autoantibody,TAA)阳性是甲肿发生的独立危险因素.(4)彰武初访时TAA阳性人群非毒性甲肿的发生率显著高于TAA阴性人群(P<0.01),盘山和黄骅无显著差异.(5)三社区非毒性弥漫型甲肿维持人群和黄骅非毒性结节型甲肿维持人群随访前后TAA阳性率均高于同社区正常人群(P<0.05).结论 碘缺乏和碘过量均有可能使甲肿的发病率增加.碘缺乏社区结节型甲肿高发,弥漫型甲肿是碘过量社区甲肿发牛的主要形式.甲状腺自身免疫与甲肿的发生和维持相关,这种相关性在历史上为碘缺乏而后过度补碘的社区更明显.     

不同碘摄入量对甲状腺肿和甲状腺结节影响的前瞻性研究

目的 研究不同碘摄入量人群非毒性甲状腺肿(甲肿)和非毒性甲状腺结节的流行病学特点及影响其发生、发展和转归的因素.方法 2004年对盘山(长期轻度碘缺乏)、彰武(碘缺乏基础上补碘至碘超足量)和黄骅(长期碘过量)社区于1999年参加本课题组流行病学研究并进行甲状腺B超检查的人群(3 385人)进行甲状腺疾病的随访调查.结果 (1)盘山、彰武和黄骅社区弥漫型甲肿的累积发病率分别为7.1%、4.4%和6.9%,盘山和黄骅均显著高于彰武(均P<0.01);结节型甲肿的累积发病率分别为5,0%、2.4%和0.8%,盘山的发病率最高(P<0.01).(2)三社区甲状腺单发结节的累积发病率分别为4.0%、5.7%和5.6%,多发结节的累积发病率分别为0.4%、1.2%和1.0%.(3)基础碘缺乏、碘过量、甲状腺自身抗体(thyroid autoantibody,TAA)阳性是甲肿发生的独立危险因素.(4)彰武初访时TAA阳性人群非毒性甲肿的发生率显著高于TAA阴性人群(P<0.01),盘山和黄骅无显著差异.(5)三社区非毒性弥漫型甲肿维持人群和黄骅非毒性结节型甲肿维持人群随访前后TAA阳性率均高于同社区正常人群(P<0.05).结论 碘缺乏和碘过量均有可能使甲肿的发病率增加.碘缺乏社区结节型甲肿高发,弥漫型甲肿是碘过量社区甲肿发牛的主要形式.甲状腺自身免疫与甲肿的发生和维持相关,这种相关性在历史上为碘缺乏而后过度补碘的社区更明显.     

不同碘摄入量对甲状腺肿和甲状腺结节影响的前瞻性研究

目的 研究不同碘摄入量人群非毒性甲状腺肿(甲肿)和非毒性甲状腺结节的流行病学特点及影响其发生、发展和转归的因素.方法 2004年对盘山(长期轻度碘缺乏)、彰武(碘缺乏基础上补碘至碘超足量)和黄骅(长期碘过量)社区于1999年参加本课题组流行病学研究并进行甲状腺B超检查的人群(3 385人)进行甲状腺疾病的随访调查.结果 (1)盘山、彰武和黄骅社区弥漫型甲肿的累积发病率分别为7.1%、4.4%和6.9%,盘山和黄骅均显著高于彰武(均P<0.01);结节型甲肿的累积发病率分别为5,0%、2.4%和0.8%,盘山的发病率最高(P<0.01).(2)三社区甲状腺单发结节的累积发病率分别为4.0%、5.7%和5.6%,多发结节的累积发病率分别为0.4%、1.2%和1.0%.(3)基础碘缺乏、碘过量、甲状腺自身抗体(thyroid autoantibody,TAA)阳性是甲肿发生的独立危险因素.(4)彰武初访时TAA阳性人群非毒性甲肿的发生率显著高于TAA阴性人群(P<0.01),盘山和黄骅无显著差异.(5)三社区非毒性弥漫型甲肿维持人群和黄骅非毒性结节型甲肿维持人群随访前后TAA阳性率均高于同社区正常人群(P<0.05).结论 碘缺乏和碘过量均有可能使甲肿的发病率增加.碘缺乏社区结节型甲肿高发,弥漫型甲肿是碘过量社区甲肿发牛的主要形式.甲状腺自身免疫与甲肿的发生和维持相关,这种相关性在历史上为碘缺乏而后过度补碘的社区更明显.     

不同碘摄入量对甲状腺肿和甲状腺结节影响的前瞻性研究

目的 研究不同碘摄入量人群非毒性甲状腺肿(甲肿)和非毒性甲状腺结节的流行病学特点及影响其发生、发展和转归的因素.方法 2004年对盘山(长期轻度碘缺乏)、彰武(碘缺乏基础上补碘至碘超足量)和黄骅(长期碘过量)社区于1999年参加本课题组流行病学研究并进行甲状腺B超检查的人群(3 385人)进行甲状腺疾病的随访调查.结果 (1)盘山、彰武和黄骅社区弥漫型甲肿的累积发病率分别为7.1%、4.4%和6.9%,盘山和黄骅均显著高于彰武(均P<0.01);结节型甲肿的累积发病率分别为5,0%、2.4%和0.8%,盘山的发病率最高(P<0.01).(2)三社区甲状腺单发结节的累积发病率分别为4.0%、5.7%和5.6%,多发结节的累积发病率分别为0.4%、1.2%和1.0%.(3)基础碘缺乏、碘过量、甲状腺自身抗体(thyroid autoantibody,TAA)阳性是甲肿发生的独立危险因素.(4)彰武初访时TAA阳性人群非毒性甲肿的发生率显著高于TAA阴性人群(P<0.01),盘山和黄骅无显著差异.(5)三社区非毒性弥漫型甲肿维持人群和黄骅非毒性结节型甲肿维持人群随访前后TAA阳性率均高于同社区正常人群(P<0.05).结论 碘缺乏和碘过量均有可能使甲肿的发病率增加.碘缺乏社区结节型甲肿高发,弥漫型甲肿是碘过量社区甲肿发牛的主要形式.甲状腺自身免疫与甲肿的发生和维持相关,这种相关性在历史上为碘缺乏而后过度补碘的社区更明显.     

不同碘摄入量对甲状腺肿和甲状腺结节影响的前瞻性研究

目的 研究不同碘摄入量人群非毒性甲状腺肿(甲肿)和非毒性甲状腺结节的流行病学特点及影响其发生、发展和转归的因素.方法 2004年对盘山(长期轻度碘缺乏)、彰武(碘缺乏基础上补碘至碘超足量)和黄骅(长期碘过量)社区于1999年参加本课题组流行病学研究并进行甲状腺B超检查的人群(3 385人)进行甲状腺疾病的随访调查.结果 (1)盘山、彰武和黄骅社区弥漫型甲肿的累积发病率分别为7.1%、4.4%和6.9%,盘山和黄骅均显著高于彰武(均P<0.01);结节型甲肿的累积发病率分别为5,0%、2.4%和0.8%,盘山的发病率最高(P<0.01).(2)三社区甲状腺单发结节的累积发病率分别为4.0%、5.7%和5.6%,多发结节的累积发病率分别为0.4%、1.2%和1.0%.(3)基础碘缺乏、碘过量、甲状腺自身抗体(thyroid autoantibody,TAA)阳性是甲肿发生的独立危险因素.(4)彰武初访时TAA阳性人群非毒性甲肿的发生率显著高于TAA阴性人群(P<0.01),盘山和黄骅无显著差异.(5)三社区非毒性弥漫型甲肿维持人群和黄骅非毒性结节型甲肿维持人群随访前后TAA阳性率均高于同社区正常人群(P<0.05).结论 碘缺乏和碘过量均有可能使甲肿的发病率增加.碘缺乏社区结节型甲肿高发,弥漫型甲肿是碘过量社区甲肿发牛的主要形式.甲状腺自身免疫与甲肿的发生和维持相关,这种相关性在历史上为碘缺乏而后过度补碘的社区更明显.