Objective To understand the implementation of preventive measures for iodine deficiency disorders among residents in Yunnan Province.Methods Iodized salt monitoring database and reports from states (cities) of Yunnan Province from 2011 to 2015 were collected,and the coverage rate of iodized salt,the quality of iodized salt,the rate of qualified iodized salt consumption were evaluated.Results From 2011 to 2015,at the province level,the coverage rate of iodized salt was ＞ 98％.The rate of qualified iodized salt consumption was ＞ 97％ from 2011 to 2012,and kept at higher than 95％ from 2013 to 2015.At the county level,the county (city,district) coverage rate of qualified iodized salt that ≥90％ accounted for 99.22％ (128/129),98.44％ (126/128),91.47％ (118/129),92.25％ (119/129) and 99.22％ (128/129).The constitute ratio of salt containing 18-33 mg/kg iodine increased year by year,from 64.07％ (24 297/37 923) in 2011 to 95.15％ (36 930/38 813) in 2015.Conclusions In recent years,measures for control of iodine deficiency disorders are implemented well in Yunnan Province.After production of new standard iodized salt in 2012,the rate of qualified iodized salt consumption is decreased.After the four-year transition period,the new standard iodized salt has covered over the whole province.To rectify salt market,improve quality of iodized salt and enhance monitoring quality in order to consolidate the control achievements is the focus of prevention work in the future.

Objective To analyze the iodine nutritional status in the key populations before and after the adjustment of iodized salt in Yunnan Province,and to provide scientific basis for adjusting the strategy of prevention and treatment timely.Methods The probability proportional to size sampling method was employed in the investigation.In the pre-adjustment period (2011) and the post-adjustment period (2014),the changes in the residents' iodized salt,the urinary iodine and goiter prevalence of children aged 8-10,the urinary iodine of pregnant women and lactating women were analyzed.Results Before and after adjusting the salt iodine concentration,the coverage rate of iodized salt was 99.1％ (1 196/1 207) and 99.2％ (1 532/1 545),respectively,the mean of salt iodine after the adjustment (23.6 mg/kg) was significantly lower than that of before (30.1 mg/kg,F =17.287,P ＜ 0.01).There was significant difference in the iodine nutritional status of children from 271.4 to 180.9 μg/L (Z=-12.883,P ＜ 0.01).The difference of iodine nutritional status in pregnant women between pre-adjustment (217.3 μg/L) and postadjustment (143.7 μg/L) was also significant (Z =9.997,P ＜ 0.01).The thyroid goiter rate of children had inceased from 1.7％ (21/1 207) to 2.1％ (33/1 549),the difference was not statistically significant between the groups (x2=0.539,P ＞ 0.05).Conclusions After adjusting the salt iodine concentration in Yunnan Province,iodine nutrition of children has decreased from more than adequate level to adequate level,thyroid goiter rate of children has remained at the low level,and iodine nutrition of pregnant women is sightly lower than adequate level,but iodine deficiency of pregnant women is at a low risk because of the good iodized salt coverage.The new standard of iodized salt is appropriate,and it is more favorable to health in Yunnan Province.

Objective:To investigate the iodine nutritional status of adults and pregnant women in Jianshui County and Zhenxiong County, Yunnan Province.Methods:From May to August 2021, one urban area and one rural area in Jianshui County and Zhenxiong County, Yunnan Province were selected as investigation sites. At least 100 adults (half male and half female) and 100 pregnant women were selected as survey subjects in each investigation site. Random urine samples were collected from all survey subjects once to detect urine iodine, creatinine and sodium contents. Venous blood samples of all pregnant women were collected to detect the serum iodine content, and the 95% medical reference range of serum iodine was established using the percentile method.Results:The medians urinary iodine, creatinine and sodium of adults in Jianshui County and Zhenxiong County were 184.7 μg/L ( n = 432), 12 355.0 μmol/L ( n = 431) and 156.5 mmol/L ( n = 420), respectively. The median urinary iodine of adults in Jianshui County was higher than that in Zhenxiong County (197.3 vs 170.2 μg/L), the difference was statistically significant ( Z = - 2.90, P = 0.003). The median serum iodine of pregnant women in Jianshui County and Zhenxiong County was 92.1 μg/L ( n = 412), with a 95% medical reference value ranged from 45.3 to 183.5 μg/L; the medians urinary iodine, creatinine and sodium of pregnant women were 138.6 μg/L ( n = 413), 12 173.0 μmol/L ( n = 408) and 152.2 mmol/L ( n = 409), respectively. The urinary iodine (154.1 vs 115.8 μg/L), urinary creatinine (13 216.0 vs 11 376.0 μmol/L) and urinary sodium (161.8 vs 141.8 mmol/L) of pregnant women in Jianshui County were higher than those in Zhenxiong County, with statistical differences ( Z = - 5.12, - 2.29, - 4.30, P < 0.05). Conclusion:Adults in Jianshui County and Zhenxiong County are at an appropriate level of iodine, but pregnant women in Zhenxiong County are at an iodine deficiency level.

Objective:To investigate the relationship between tube voltage kV value for head and neck CT angiography and body weight.Methods:A total of 120 patients with suspected vascular disease of the head and neck who underwent CT angiography of the head and neck in Beihai People's Hospital from January 2020 to May 2022 were included in this study. Patients were divided into three groups according to different tube voltages: group A (tube voltage 120 kV, n = 45), group B (tube voltage 100 kV, n = 45) and group C (tube voltage 80 kV, n = 30). Patients in group A were divided into group A1 (< 70 kg, n = 15), group A2 (70-85 kg, n = 15) and group A3 (> 85 kg, n = 15) according to different body weights. Patients in group B were divided into group B1 (< 70 kg, n = 15), group B2 (70-85 kg, n = 15) and group B3 (> 85 kg, n = 15) according to different body weights. Patients in group C were divided into group C1 (< 70 kg, n = 15) and group C2 (70-85 kg, n = 15) according to different body weights. Group C3 was not used. The contrast medium used was Loversol. The CT value, image noise, signal-to-noise ratio, contrast to noise ratio, and effective radiation dose of arterial vessels in each group were measured. The images were subjectively evaluated by two physicians who had senior professional titles using a 5-point rating scale. Results:Subjective score of image quality was all ≥ 3 grade in each group. There was no significant difference in image quality rating between groups A1 and A2 and groups B1, B2, and C1. There was a remarkable difference in image quality rating between groups A3, B3, and C2 and the other groups. There was a significant difference in the CT value of blood vessels at four different levels between groups A1, B1 and C1 ( F = 76.82, 64.62, 98.79, 71.85, all P < 0.001). There was a significant difference in CT value of blood vessels at four different levels between groups A2, B2 and C2 ( F = 159.82, 112.33, 108.22, 135.18, all P < 0.001). There was a significant difference in CT value of blood vessels at four different levels between groups A3 and B3 ( t = 4.40, 4.27, 3.91, 3.59, all P < 0.05). In groups B3 and C2, the image noise was remarkably increased, signal to noise ratio and contrast to noise ratio were remarkably decreased compared with those in the other groups. The effective radiation dose of arterial vessels in group B1 was 47% lower than that in group A1 and the effective radiation dose of arterial vessels in group C1 was 73% lower than that in group A1 ( F = 116.18, P < 0.001). The effective radiation dose of arterial vessels in group B2 was 49% lower than that in group A2, and the effective radiation dose of arterial vessels in group C2 was 66% lower than that in group A2 ( H = 35.40, P < 0.001). The effective radiation dose in group B3 was 35% lower than that in group A3 ( t = 3.59, P < 0.05). Conclusion:In CT angiography of the head and neck, the selection of tube voltage kV value is related to body weight. Tube voltage 80 kV is suitable for patients with a body weight < 70 kg, tube voltage 100 kV for patients with a body weight of 70-85 kg, and tube voltage 120 kV for patients with a body weight > 85 kg. These tube voltages can decrease effective radiation dose and ensure image quality, meeting the requirement for clinical diagnosis.

Objective To understand the situation of iodine deficiency disorders and iodine nutrition of children in Yunnan Province after the implementation of new standard of salt iodine,and provide the basic data for prevention and control of iodine deficiency disorders.Methods Using multistage sampling method,Yunnan provincial evaluations for iodine deficiency disorders elimination were carried out.According to the comparative analysis of 2010 (pre-adjustment) and 2015 (post-adjustment) evaluation results,the changes of the median of salt iodine,the coverage rate of iodized salt,the qualified rate of iodized salt,the rate of qualified iodized salt consumption,goiter rate of school children aged 8-10 and the median of urinary iodine were evaluated.Salt iodine was tested using the "Salt Industry General Test Method for Determination of Iodine" (GB/T 13025.7-1999);thyroid volume examination of children using B-scan ultrasonography,thyroid volume calculation and enlargement judgment using "Diagnostic Criteria for Endemic Goiter" (WS 276-2007);and urinary iodine detection using "Urinary Iodine Arsenic Cerium Catalytic Spectrophotometry" (WS/T 107-2006).Results The medians of salt iodine in 2010 and 2015 were 30.6 and 22.4 mg/kg,respectively,the difference was statistically significant (U =317 503.50,P ＜ 0.01).The coverage rates of iodized salt in 2010 and 2015 were 99.6％ (1 681/1 688) and 98.9％ (2 592/2 622),the qualified rates of iodized salt were 98.6％ (1 657/1 681) and 89.7％ (2 325/2 592),and the rates of qualified iodized salt consumption were 98.2％ (1 657/1 688) and 88.7％ (2 325/2 622),and the differences were statistically significant (x2 =6.42,125.11,130.18,P ＜ 0.01);the rates of children goiter in 2010 and 2015 were 0.8％ (25/3 272) and 1.4％(44/3 245),respectively;the medians of urinary iodine of children were 289.0 and 157.3 μg/L,respectively,the difference was statistically significant (U =1 121 669.50,P ＜ 0.01).Conclusion After decreasing of salt iodine level starting from 2012 in Yunnan Province,the children iodine nutrition condition is in a more proper level.

Objective:To analyze the influencing factors of thyroid volume in children aged 8 - 10 in Yunnan Province, and provide scientific basis for improving iodine deficiency disorders monitoring.Methods:From March to July 2020, in 129 counties (cities, districts) under the jurisdiction of Yunnan Province, each county (city, district) was divided into 5 sampling areas based on east, west, south, north, and middle. One township was selected from each area, and 40 non-boarding children aged 8 - 10 from one primary school were selected from each township (age balanced, half male and half female) as survey subjects. One random urine sample and household edible salt samples were collected for urine iodine and salt iodine testing, and physical examination and thyroid volume measurement were conducted for children. The influencing factors of thyroid volume were analyzed using Pearson correlation.Results:A total of 24 934 urine samples were collected from children, with a median urine iodine of 233.2 μg/L. A total of 24 933 household edible salt samples were collected from children, the median salt iodine was 24.17 mg/kg, and the qualified rate of iodized salt was 96.63% (24 003/24 839); A total of 24 937 children were examined of their thyroid gland, with a median thyroid volume of 2.62 ml and a goiter rate of 1.12% (280/24 937). Among them, there were 12 410 boys and 12 527 girls, with thyroid volumes of 2.61 and 2.64 ml, respectively. The thyroid volume of boys was positively correlated with age, height, weight, body mass index, body surface area, and salt iodine ( r = 0.15, 0.21, 0.26, 0.18, 0.25, 0.03, P < 0.001). The thyroid volume of girls was positively correlated with age, height, weight, body mass index, and body surface area ( r = 0.17, 0.26, 0.28, 0.17, 0.27, P < 0.001). Conclusion:Children aged 8 - 10 in Yunnan Province are at an iodine excess level; the age, weight, height, body mass index, and body surface area are influencing factors of thyroid volume.

Objective:To understand the contents of edible salt iodine and urinary iodine of children and pregnant women in Yunnan Province, and to evaluate the iodine nutrition status, so as to provide a basis for scientific prevention and treatment of iodine deficiency disorders (IDD).Methods:From November to December 2020, one county (city) was selected from each prefecture (city), two townships (towns and streets) were selected from each county (city) and two villages (neighborhood committees) were selected from each township (town and street) from each of the 16 prefectures (cities) in Yunnan Province as the investigation sites. A total of 20 non-boarding children (male and female balanced) aged 8 - 10 years old were selected from each primary school in each village (neighborhood committee) to collect salt and urine samples. A total of 80 children were investigated in each county (city). A total of 20 pregnant women were selected from each township (town and street) to collect salt and urine samples. A total of 40 pregnant women were investigated in each county (city). All salt samples and urine samples were tested for iodine contents.Results:A total of 2 009 salt samples and 2 041 urine samples (1 375 for children, 666 for pregnant women) were collected from children aged 8 - 10 years old and pregnant women in 16 counties (cities) of Yunnan Province. Among them, the median salt iodine was 26.0 mg/kg, the coverage rate of iodized salt was 100.0% (2 009/2 009), the qualified rate of iodized salt was 98.7% (1 982/2 009), and the consumption rate of qualified iodized salt was 98.7% (1 982/2 009). The difference of salt iodine content in key populations in different counties (cities) was statistically significant ( H = 258.98, P < 0.01). The median urinary iodine of children aged 8 - 10 years old was 188.5 μg/L. There was statistically significant difference in urinary iodine content among children of different ages ( H = 29.45, P < 0.01), but there was no statistically significant difference in urinary iodine content among children of different genders ( H = 1.43, P > 0.05). In addition, the median urinary iodine of pregnant women was 141.9 μg/L, 52.1% (347/666) was < 150 μg/L. There was statistically significant difference in urinary iodine content of pregnant women in different counties (cities, H = 88.32, P < 0.01). Conclusions:The qualified rate of iodized salt, the coverage rate of iodized salt and the consumption rate of qualified iodized salt in key populations of Yunnan Province are more than 90%, and the iodized salt supply is good. Iodine nutrition of children aged 8 - 10 years old is at an appropriate level (100 - 199 μg/L); iodine nutrition of pregnant women is in an state of iodine deficiency ( < 150 μg/L). It is suggested to strengthen IDD monitoring and health education among key populations, improve residents' awareness of disease prevention, and make scientific iodine supplementation.

OBJECTIVEIn order to understand the iodine nutritional status, after the salt-iodine content was showed a reduction in 2012 and to evaluate the current situation after the new standards was brought into force to the general population in an experimental community of Yunnan province.

METHODSRandomly sampled urine and salt were collected, to test the iodine concentration in the study-site. Pre-and post-levels of the iodized salt under the provision of the new standards, were identified.

RESULTSof this study were gathered upon 3 weeks or 3 months, respectively. Results Data from the three randomly chosen study sites showed that the urine iodine concentration in the general populations was reducing gradually. In the general population, medians of Urine Iodine (MUI) were 279.71 µg/L, 239.64 µg/L and 226.26 µg/L, respectively. Proportion of the urine iodine value for 100-199 µg/L increased but ≥300 µg/L decreased, after the new standard was put into practice. Both homogeneity and stability of the new standard on iodized salt seemed to be good.

CONCLUSIONIodine nutrition in general population appeared reasonable under the use of newly set salt-iodine standards in general population living in Yunnan province.

China ; Humans ; Iodine ; administration & dosage ; analysis ; urine ; Nutrition Policy ; Nutritional Status ; Sodium Chloride, Dietary ; administration & dosage ; analysis