[1]刘 萍,曾佩佩,覃荣娟,等.早产低体重儿及足月儿身体成分差异分析[J].医学信息,2023,36(16):89-92.[doi:10.3969/j.issn.1006-1959.2023.16.016]
 LIU Ping,ZENG Pei-pei,QIN Rong-juan,et al.Analysis of Body Composition Differences Between Preterm Low Birth Weight Infant and Term Infant[J].Journal of Medical Information,2023,36(16):89-92.[doi:10.3969/j.issn.1006-1959.2023.16.016]
点击复制

早产低体重儿及足月儿身体成分差异分析()
分享到:

医学信息[ISSN:1006-1959/CN:61-1278/R]

卷:
36卷
期数:
2023年16期
页码:
89-92
栏目:
论著
出版日期:
2023-08-15

文章信息/Info

Title:
Analysis of Body Composition Differences Between Preterm Low Birth Weight Infant and Term Infant
文章编号:
1006-1959(2023)16-0089-04
作者:
刘 萍曾佩佩覃荣娟
(柳州市妇幼保健院儿童保健科,广西 柳州 545001)
Author(s):
LIU PingZENG Pei-peiQIN Rong-juanet al.
(Child Health Care Department of Liuzhou Maternity and Child Healthcare Hospital,Liuzhou 545001,Guangxi,China)
关键词:
早产儿低出生体重儿人体成分生物电阻抗
Keywords:
Preterm infantsLow birth weight infantsHuman compositionBioelectrical impedance
分类号:
R722.6
DOI:
10.3969/j.issn.1006-1959.2023.16.016
文献标志码:
A
摘要:
目的 分析早产低出生体重儿与足月儿身体成分差异。方法 选取2021年8月-2022年2月柳州市妇幼保健院出生的早产低出生体重儿51例及足月出生儿51例,分为早产低体重儿组及足月儿组。采用生物电阻抗法分别测量相位角、脂肪、人体总水量、细胞外液、细胞内液、干瘦肉、身体瘦肉、体重指数、营养指数、预测指数、骨骼肌肉群等,比较不同时间两组婴儿人体成分差异。结果 出生后第1天,足月儿组体重指数、总水分、干瘦肉、基础代谢率、体细胞质量及相位角检测值均高于早产低体重儿组(P<0.05),脂肪、骨骼肌肉群含量低于早产低体重新生儿(P<0.05);出生后第2、3天,足月儿组体重指数、总水分、干瘦肉、基础代谢率、体细胞质量及相位角检测值均高于早产低体重儿组(P<0.05);两组脂肪含量、骨骼肌肉群比较,差异无统计学意义(P>0.05)。结论 早产低体重新生儿体重指数、总水分、干瘦肉、基础代谢率、体细胞质量及相位角与足月新生儿差异明显,脂肪及骨骼肌肉群含量在早产低体重儿与足月儿中是否存在差异仍需大样本研究进一步验证。
Abstract:
Objective To analyze the body composition difference between preterm low birth weight infant and term infant.Methods A total of 51 premature low birth weight infants and 51 term infants born in Liuzhou Maternal and Child Healthcare Hospital from August 2021 to February 2022 were selected and divided into premature low birth weight infants group and term infants group. The phase angle, fat, total body water, extracellular fluid, intracellular fluid, dry lean meat, body lean meat, body mass index, nutritional index, predictive index and skeletal muscle group were measured by bioelectrical impedance method, and the differences of body composition between the two groups at different times were compared.Results On the first day after birth, the body mass index, total body water, dry lean meat, basal metabolic rate, somatic cell mass and phase angle of term infants group were higher than those of premature low birth weight infants group (P<0.05), and the contents of fat and skeletal muscle group were lower than those of premature low birth weight infants group (P<0.05). On the 2nd and 3rd day after birth, the body mass index, total body water, dry lean meat, basal metabolic rate, somatic cell mass and phase angle detection values of the term infants group were higher than those of the premature low birth weight infants group (P<0.05), while there was no significant difference in fat content and skeletal muscle group between the two groups (P>0.05).Conclusion The body mass index, total moisture, dry lean meat, basal metabolic rate, somatic cell mass and phase angle of preterm low birth weight infants are significantly different from those of term infants. Whether there are differences in fat and skeletal muscle group content between preterm low birth weight infants and term infants still needs to be further verified by large sample studies.

参考文献/References:

[1]黄晓凤,张悦,吕金昌,等.北京市顺义区学龄儿童少年体重指数与体脂百分比关系的研究[J].医学信息,2019,32(7):134-136.[2]刘军廷,刘功姝,吴艳华,等.生物电阻抗法测量3-6岁儿童体成分的准确性[J].中华实用儿科临床杂志,2021,36(2):104-108.[3]刘冬,田海波.基于生物电阻抗儿童体成分检测与分析[J].电子世界,2020(7):19-20.[4]陈芳芳,刘军廷,黄贵民,等.中国7个城市3-17岁儿童青少年体成分调查[J].中华流行病学杂志,2020,41(2):213-214.[5]王璐璐,张倩.儿童青少年的体成分研究[J].中国儿童保健杂志,2018,26(12):1332-1335.[6]吴江月,陈立新,贾志伟,等.不同体型儿童的体成分分析[J].中国妇幼健康研究,2021,32(11):1628-1632.[7]苏月月,王虹,李晴,等.不同性别、年龄及营养状态儿童的人体成分分析[J].中国儿童保健杂志,2021,29(7):713-716.[8]English LK,Obbagy JE,Wong YP,et al.Timing of introduction of complementary foods and beverages and growth, size, and body composition: a systematic review[J].Am J Clin Nutr,2019,109(Suppl-7):935S-955S.[9]Przybylska PP,Sitek A,Rosset I,et al.The association between socioeconomic status, duration of breastfeeding, parental age and birth parameters with BMI, body fat and muscle mass among prepubertal children in Poland[J].Anthropol Anz,2019,76(5):409-419.[10]Sanchez-escobedo S,Azcorra H,Bogin B,et al.Birth weight, birth order, and age at first solid food introduction influence child growth and body composition in 6- to 8- year-old Mays children: The importance of the first 1000 days of life[J].Am J Hum Biol,2020,32(5):e23385.[11]Chawanpaiboon S,Vogel JP,Moller AB,et al.Global,regional,and national estimates of levels of preterm birth in 2014:a systematic review and modelling analysis[J].Lancet Glob HeaIth,2019,7(1):e37-e46.[12]WHO.Global nutrition targets 2025:low birth weight policy brief[M].Geneva:World Health Organization,2014.[13]中华预防医学会儿童保健分会.婴幼儿喂养与营养指南[J].中国妇幼健康研究,2019,30(4):392-417.[14]中国医师学会新生儿科医师分会循证专业委员会.早产儿喂养不耐受临床诊疗指南[J].中国当代儿科杂志,2020,22(10):1047-1055.[15]张蓉,林新祝,常艳美,等.早产儿支气管肺发育不良营养管理专家共识[J].中国当代儿科杂志,2020,22(8):805-814.[16]Sakers A,De Siqueira MK,Seale P,et al.Adipose-tissue plasticity in health and disease[J].Cell,2022,185(3):419-446.[17]Anand SS,Friedrich MG,Lee DS,et al.Evaluation of Adiposity and Cognitive Function in Adults[J].JAMA Network Open,2022,5(2):e2146324.[18]Moonen H,Van Zanten ARH.Bioelectric impedance analysis for body composition measurement and other potential clinical application in critical illness[J].Current Opinion in Critical Care,2021,27(4):344-353.[19]Gupta D,Lammersfeld CA,Vashi PG,et al.Bioelectrical impedance phase angle in clinical practice: implications for prognosis in stage IIIB and IV non-small cell lung cancer[J].BMC Cancer,2009,9:37.

相似文献/References:

[1]石福建.N-CPAP模式和NIPPV对呼吸窘迫综合征早产儿心功能的影响分析[J].医学信息,2018,31(02):91.[doi:10.3969/j.issn.1006-1959.2018.02.031]
 SHI Fu-jian.Effect of N-CPAP Mode and NPIPPV on Cardiac Function in Preterm Infants with Respiratory Distress Syndrome[J].Journal of Medical Information,2018,31(16):91.[doi:10.3969/j.issn.1006-1959.2018.02.031]
[2]刘亿荣,吴开锋,曾春英,等.早产儿肠道喂养方式对住院期间变应性疾病的影响[J].医学信息,2018,31(02):105.[doi:10.3969/j.issn.1006-1959.2018.02.037]
 LIU Yi-Rong,WU Kai-Feng,ZENG Chun-Ying,et al.Effects of Gut Feeding on Preterm Infant Allergic Diseases during Hospitalization[J].Journal of Medical Information,2018,31(16):105.[doi:10.3969/j.issn.1006-1959.2018.02.037]
[3]赵 菁.脐带不同结扎方式对新生儿影响的研究进展[J].医学信息,2018,31(04):53.[doi:10.3969/j.issn.1006-1959.2018.04.017]
 ZHAO Jing.Research Progress on the Influence of Different Umbilical Cord Ligation on Neonates[J].Journal of Medical Information,2018,31(16):53.[doi:10.3969/j.issn.1006-1959.2018.04.017]
[4]董显燕,高李华.BNP及NT-proBN诊断早产儿动脉导管未闭临床分析[J].医学信息,2019,32(12):70.[doi:10.3969/j.issn.1006-1959.2019.12.022]
 DONG Xian-yan,GAO Li-hua.Clinical Analysis of BNP and NT-proBN in the Diagnosis of Patent Ductus Arteriosus in Premature Infants[J].Journal of Medical Information,2019,32(16):70.[doi:10.3969/j.issn.1006-1959.2019.12.022]
[5]龙小红.枸橼酸咖啡因对早产儿原发性呼吸暂停及相关并发症的影响[J].医学信息,2019,32(22):130.[doi:10.3969/j.issn.1006-1959.2019.22.043]
 LONG Xiao-hong.Effect of Caffeine Citrate on Primary Apnea and Related Complications in Premature Infants[J].Journal of Medical Information,2019,32(16):130.[doi:10.3969/j.issn.1006-1959.2019.22.043]
[6]沙春娜,张海鸿.枸橼酸咖啡因治疗早产儿呼吸暂停及预防支气管肺发育不良的效果[J].医学信息,2020,33(02):142.[doi:10.3969/j.issn.1006-1959.2020.02.042]
 SHA Chun-na,ZHANG Hai-hong.Effect of Caffeine Citrate on Apnea and Prevention of Bronchopulmonary Dysplasia in Preterm Infants[J].Journal of Medical Information,2020,33(16):142.[doi:10.3969/j.issn.1006-1959.2020.02.042]
[7]于 波.静脉注射丙种球蛋白治疗早产儿肺炎临床疗效[J].医学信息,2020,33(04):149.[doi:10.3969/j.issn.1006-1959.2020.04.048]
 YU Bo.Clinical Efficacy of Intravenous Gamma Globulin in Premature Infants with Pneumonia[J].Journal of Medical Information,2020,33(16):149.[doi:10.3969/j.issn.1006-1959.2020.04.048]
[8]张 敏,蒙好好,廖爱玲,等.母乳库母乳喂养对早产儿生长发育的影响[J].医学信息,2020,33(08):176.[doi:10.3969/j.issn.1006-1959.2020.08.060]
 ZHANG Min,MENG Hao-hao,LIAO Ai-ling,et al.Effect of Breastfeeding in Breast Milk Bank on Growth and Development of Premature Infants[J].Journal of Medical Information,2020,33(16):176.[doi:10.3969/j.issn.1006-1959.2020.08.060]
[9]李 玲,邸晓飞.NICU早产儿低体温原因分析及护理[J].医学信息,2020,33(19):48.[doi:10.3969/j.issn.1006-1959.2020.19.015]
 LI Ling,DI Xiao-fei.Analysis of the Causes of Hypothermia in Premature Infants in NICU and Its Nursing[J].Journal of Medical Information,2020,33(16):48.[doi:10.3969/j.issn.1006-1959.2020.19.015]
[10]章晓雨,童 玲,王慧琴.早产小于胎龄儿的临床特点及高危因素分析[J].医学信息,2020,33(23):96.[doi:10.3969/j.issn.1006-1959.2020.23.027]
 ZHANG Xiao-yu,TONG Ling,WANG Hui-qin.Clinical Characteristics and High Risk Factors of Premature Infants with Small for Gestational Age[J].Journal of Medical Information,2020,33(16):96.[doi:10.3969/j.issn.1006-1959.2020.23.027]
[11]曾 婷,曾佩佩,覃荣娟,等.并发病理性黄疸早产低出生体重儿体成分分析[J].医学信息,2024,37(11):89.[doi:10.3969/j.issn.1006-1959.2024.11.016]
 ZENG Ting,ZENG Pei-pei,QIN Rong-juan,et al.Analysis of Body Composition of Premature Low Birth Weight Infants with Pathological Jaundice[J].Journal of Medical Information,2024,37(16):89.[doi:10.3969/j.issn.1006-1959.2024.11.016]

更新日期/Last Update: 1900-01-01