孕早期女性铁营养状况及其影响因素分析

doi:10.19723/j.issn.1671-167X.2023.04.005

摘要/Abstract

摘要：

目的: 探讨膳食等因素对孕早期女性铁营养状况的影响，为预防铁缺乏及缺铁性贫血，降低相关不良母婴健康结局发生风险提供研究依据。方法: 在2018年11月至12月于北京儿童医院顺义妇儿医院建档产检的孕早期女性中共招募到388名孕早期女性为研究对象，收集其人口统计特征、人体测量特征、分娩史、孕早期铁营养状况指标和膳食频率信息。统计分析采用SPSS 26.0软件，各组间铁营养状况差异分析采用Fisher精确概率检验或单因素方差分析，均为双侧概率检验，P＜0.05为差异有统计学意义。采用主成分分析提取膳食模式，计算各膳食模式因子得分。以血清铁蛋白(serum ferritin, SF)＜30 μg/L为铁缺乏标准，采用Logistic回归方法分析上述因素对孕早期铁缺乏症的影响。结果: 研究对象平均血清铁蛋白水平为(50.4±35.3) μg/L，共有铁缺乏者121例(31.2%)，其中铁减少(iron depletion, ID)、缺铁性红细胞生成(iron deficiency erythropoiesis, IDE)和缺铁性贫血(iron deficiency anemia, IDA)分别为107例(27.6%)、8例(2.1%)和6例(1.5%)。分娩史是孕早期女性铁缺乏的危险因素，OR=3.90(95%CI: 1.81~8.42, P=0.001)。反之，孕妇年龄每增加1岁，患病风险即降低4%(95%CI: 0.94~0.97, P＜0.001)，年龄是铁缺乏症的保护因素。服用含铁营养补充剂对有分娩史的女性存在显著保护作用(OR=0.27, 95%CI: 0.09~0.83, P=0.022)。荤素均衡膳食模式(OR=0.81, 95%CI: 0.66~1.00, P=0.054)对铁缺乏症的影响具有边缘显著性。结论: 应对经产妇及年轻孕妇的铁营养状况予以充分关注，对于育龄女性群体，特别是经产妇，在备孕期及孕早期推荐使用含铁补充剂，以预防孕期铁缺乏症；荤素均衡膳食模式对孕早期铁缺乏症的影响仍需进一步研究予以确定。

关键词: 铁缺乏, 缺铁性贫血, 患病率, 危险因素, 孕期

Abstract:

Objective: To investigate the impact of dietary and underlying factors on the iron status of women in early pregnancy and to provide evidence for preventing iron deficiency and iron deficiency anemia, thereby reducing the incidence of associated adverse outcomes. Methods: From November to December 2018, women in the first trimester of pregnancy (< 12 weeks gestation) who established prenatal records at the Shunyi District Maternal and Child Health Hospital, Beijing, were enrolled in this study, in which 388 participants were accessed for data including demographic characteristics, anthropometric measurements, parity, biomarkers reflecting iron status, and food-frequency questionnaire. SPSS 26.0 were used for statistical analysis. Dietary patterns were extracted using principal component analysis, and factor scores of each dietary pattern were calculated. Two-sided Fisher exact probability test and one-way ANOVA were conducted to access differences in iron status among the groups, and the differences were significant if P < 0.05. Iron deficiency was defined as serum ferritin(SF) < 30 μg/L. To analyze the potential role of dietary factors on iron deficiency during the first trimester, the collected data listed above were adopted as independent factors for the cross-sectional Logistic regression. We used Logistic regression to analyze the potential effects of baseline characteristics and dietary factors on iron status. Results: Among the 388 participants included in the analysis, 121 (32.2%) were iron deficient, in which 107 (27.6%) were iron depletion (ID), 8 (2.1%) were iron deficiency erythropoiesis (IDA), 6(1.5%) were iron deficiency anemia. The mean SF concentration was (50.4±35.3) μg/L. Multiparity(OR=3.9, 95%CI: 1.81-8.42, P=0.001)was a risk factor for iron deficiency during early pregnancy. No significant iron status differences were found among the participants with different educational levels and anthropometric measurements. In contrast, age (OR =0.96, 95%CI: 0.94-0.97, P < 0.001) was a protective factor. For multiparas, taking iron-containing supplements might have a protective effect for iron deficiency (OR=0.27, 95%CI: 0.09-0.83, P=0.022). The balance-diet pattern (OR=0.81, 95%CI: 0.66-1.00, P=0.054) only showed a marginally significant effect. Conclusion: Increasing attention should be paid to the iron status of pregnant multiparas and young pregnant women. For those women of reproductive age with the risk factors listed above, especially for multiparas, iron-containing supplements should be recommended to prevent gestational iron deficiency. The effect of the "balance" dietary pattern on iron status in the first trimester and following requires further research and discussion.

Key words: Iron deficiency, Iron deficiency anemia, Prevalence, Risk factor, Pregnancy

中图分类号:

R153.1

林咏惟,周雅琳,赵润茏,许雅君,刘燕萍. 孕早期女性铁营养状况及其影响因素分析[J]. 北京大学学报（医学版）, 2023, 55(4): 600-605.

Yong-wei LIN,Ya-lin ZHOU,Run-long ZHAO,Ya-jun XU,Yan-ping LIU. Analysis on the iron status and associated factors during the first trimester of pregnancy[J]. Journal of Peking University (Health Sciences), 2023, 55(4): 600-605.

图/表 4

表1

表2

表3

表4

参考文献 23

1	Pavord S , Myers B , Robinson S , et al. UK guidelines on the management of iron deficiency in pregnancy[J]. Br J Haematol, 2012, 156 (5): 588- 600. doi: 10.1111/j.1365-2141.2011.09012.x
2	Bunch K , Roberts N , Knight M , et al. Systematic review to investigate the safety of induction and augmentation of labour among pregnant women with iron-deficiency anaemia[J]. BMJ Open, 2018, 8 (12): e021793. doi: 10.1136/bmjopen-2018-021793
3	Juul SE , Derman RJ , Auerbach M . Perinatal iron deficiency: Implications for mothers and infants[J]. Neonatology, 2019, 115 (3): 269- 274. doi: 10.1159/000495978
4	Georgieff MK . Iron deficiency in pregnancy[J]. Am J Obstet Gynecol, 2020, 223 (4): 516- 524. doi: 10.1016/j.ajog.2020.03.006
5	Dewey KG , Oaks BM . U-shaped curve for risk associated with maternal hemoglobin, iron status, or iron supplementation[J]. Am J Clin Nutr, 2017, 106 (Suppl 6): S1694- S1702. doi: 10.3945/ajcn.117.156075
6	Kaufer M , Casaneuva E . Relation of pregnancy serum ferritin levels to hemoglobin levels throughout pregnancy[J]. Eur J Clin Nutr, 1990, 44 (10): 709- 715.
7	Shao J , Lou J , Rao R , et al. Maternal serum ferritin concentration is positively associated with newborn iron stores in women with low ferritin status in late pregnancy[J]. J Nutr, 2012, 142 (11): 2004- 2009. doi: 10.3945/jn.112.162362
8	Yamamoto K , Wang N , Takita M , et al. Iron deficiency anaemia: Its prevalence among women of reproductive age in Shanghai and Tokyo and links to body mass index[J]. Cureus, 2020, 12 (7): e9436.
9	Loy SL , Lim LM , Chan SY , et al. Iron status and risk factors of iron deficiency among pregnant women in Singapore: A cross-sectional study[J]. BMC Public Health, 2019, 19 (1): 397. doi: 10.1186/s12889-019-6736-y
10	Blanco-Rojo R , Toxqui L , López-Parra AM , et al. Influence of diet, menstruation and genetic factors on iron status: A cross-sectional study in Spanish women of childbearing age[J]. Int J Mol Sci, 2014, 15 (3): 4077- 4087. doi: 10.3390/ijms15034077
11	Pistollato F , Sumalla Cano S , Elio I , et al. Plant-based and plant-rich diet patterns during gestation: Beneficial effects and possible shortcomings[J]. Adv Nutr, 2015, 6 (5): 581- 591. doi: 10.3945/an.115.009126
12	Piccoli GB , Clari R , Vigotti FN , et al. Vegan-vegetarian diets in pregnancy: Danger or panacea? A systematic narrative review[J]. BJOG, 2015, 122 (5): 623- 633. doi: 10.1111/1471-0528.13280
13	中华医学会围产医学分会. 妊娠期铁缺乏和缺铁性贫血诊治指南[J]. 中华围产医学杂志, 2014, 17 (7): 451- 454. doi: 10.3760/cma.j.issn.1007-9408.2014.07.006
14	中华医学会血液学分会红细胞疾病学组. 铁缺乏症和缺铁性贫血诊治和预防多学科专家共识[J]. 中华医学杂志, 2018, 98 (28): 2233- 2237. doi: 10.3760/cma.j.issn.0376-2491.2018.28.004
15	Rahmati S , Azami M , Badfar G , et al. The relationship between maternal anemia during pregnancy with preterm birth: A systematic review and meta-analysis[J]. J Matern Fetal Neonatal Med, 2020, 33 (15): 2679- 2689. doi: 10.1080/14767058.2018.1555811
16	Tan J , He G , Qi Y , et al. Prevalence of anemia and iron deficiency anemia in Chinese pregnant women (iron women): A national cross-sectional survey[J]. BMC Pregnancy Childbirth, 2020, 20 (1): 670. doi: 10.1186/s12884-020-03359-z
17	中国儿童、孕妇、育龄妇女铁缺乏症流行病学调查协作组. 中国孕妇、育龄妇女铁缺乏症患病率调查[J]. 中华血液学杂志, 2004, 25 (11): 653- 657. doi: 10.3760/j:issn:0253-2727.2004.11.004
18	W HO . Iron deficiency anemia assessment, prevention, and control[M]. Geneva: World Health Organization, 2001: 17- 21.
19	Mei Z , Cogswell ME , Looker AC , et al. Assessment of iron status in US pregnant women from the National Health and Nutrition Examination Survey (NHANES), 1999-2006[J]. Am J Clin Nutr, 2011, 93 (6): 1312- 1320. doi: 10.3945/ajcn.110.007195
20	苏畅, 张兵, 王惠君, 等. 1989—2006年中国九省(区)居民谷类食物消费状况及变化趋势[J]. 中华预防医学杂志, 2011, 45 (9): 798- 801. doi: 10.3760/cma.j.issn.0253-9624.2011.09.007
21	Hurrell R . How to ensure adequate iron absorption from iron-fortified food[J]. Nutr Rev, 2008, 60 (Suppl 7): S7- S15.
22	刘艳华, 宁书芬, 张惠欣. 妊娠期预防性补铁时机的选择对妊娠结局的影响[J]. 中国妇幼保健, 2017, 32 (19): 4685- 4687.
23	Peña-Rosas JP , De-Regil LM , Garcia-Casal MN , et al. Daily oral iron supplementation during pregnancy[J]. Cochrane Database Syst Rev, 2015, (7): CD004736.

相关文章 15

[1]	魏慧, 张警丰, 姚中强, 赵金霞. 类风湿关节炎合并慢性病贫血患者的临床特征及相关因素[J]. 北京大学学报（医学版）, 2026, 58(2): 307-312.
[2]	赵杰, 付春, 赵秀娟, 薛海岩, 李纾, 王振洲, 朱凤雪. 胸部创伤患者在重症监护病房内发生呼吸机相关性肺炎的危险因素[J]. 北京大学学报（医学版）, 2026, 58(2): 351-358.
[3]	郭芷均, 俎明, 马超, 张贺军, 张静, 丁士刚. 同时性多发早期胃癌漏诊病灶的临床病理特征[J]. 北京大学学报（医学版）, 2026, 58(2): 410-415.
[4]	李博闻, 张强, 孙益鑫. 儿童及青年漏斗胸患者Nuss术后发生脊柱侧弯的风险预测模型建立及验证[J]. 北京大学学报（医学版）, 2025, 57(5): 941-946.
[5]	杨小勇, 张帆, 马潞林, 刘承. 前列腺导管腺癌临床特征及腺外侵犯的影响因素[J]. 北京大学学报（医学版）, 2025, 57(5): 956-960.
[6]	刘伟, 郭稳, 过哲, 李春艳, 李云龙, 刘思奇, 张亮, 宋慧. 痛风患者放射学阴性骨侵蚀的相关危险因素[J]. 北京大学学报（医学版）, 2025, 57(4): 735-739.
[7]	陆梦溪, 刘秋萍, 周恬静, 刘晓非, 孙烨祥, 沈鹏, 林鸿波, 唐迅, 高培. 基于社区人群队列的甘油三酯-葡萄糖指数与心血管病发病和死亡的关联[J]. 北京大学学报（医学版）, 2025, 57(3): 430-435.
[8]	李萍, 王海雪, 高晓, 韩亚静, 王辉, 王海俊, 牟莹莹. 基于移动健康技术对超重或肥胖孕妇体重管理的随机对照试验[J]. 北京大学学报（医学版）, 2025, 57(3): 465-472.
[9]	刘畅, 李炤, 金蕾, 刘春毅, 王春静, 张杰, 靳蕾. 母亲围受孕期服用叶酸营养素补充剂与围产儿死亡率的关系[J]. 北京大学学报（医学版）, 2025, 57(3): 473-480.
[10]	陈欣, 杨君婷, 郭金鑫, 李淑雅, 刘志科, 朱颖靓, 李奉娟, 詹思延, 郭娟娟. 2022—2024年青岛市10~59岁女性自身免疫性甲状腺病的患病率特征[J]. 北京大学学报（医学版）, 2025, 57(3): 507-513.
[11]	阿娜尔古丽·阿不都肉什提, 宋迎豪, 闫晓晋, 高永康, 刘波, 胡刚. 1990—2021年中国及全球增龄性听力损失的疾病负担与未来趋势预测[J]. 北京大学学报（医学版）, 2025, 57(3): 545-553.
[12]	杨龙傲, 金旭, 黄文初, 何丽华, 陈娟. 视屏作业人员视疲劳及干眼的流行病学调查[J]. 北京大学学报（医学版）, 2025, 57(3): 554-561.
[13]	林芳汝, 唐志辉. 种植单冠修复后种植体周健康的相关分析[J]. 北京大学学报（医学版）, 2025, 57(2): 347-353.
[14]	郭华秋, 王哲, 杨雪, 白洁. 口腔急诊出血患者的临床特征与危险因素[J]. 北京大学学报（医学版）, 2025, 57(1): 142-147.
[15]	邓敏婷, 王楠, 夏斌, 赵玉鸣, 朱俊霞. 儿童及青少年挫入恒前牙自行再萌出的相关影响因素[J]. 北京大学学报（医学版）, 2025, 57(1): 148-153.

Metrics

Viewed

Full text

Abstract

Cited

Shared

Discussed

Items	Normal/%	Iron deficiency/%				P
Items	Normal/%	Total	ID	IDE	IDA	P
Age/years						0.235
20-25 (n=50)	66.0	4.4	34.0	0.0	0.0
26-30 (n=213)	69.5	16.8	27.7	1.9	0.9
31-35 (n=102)	71.6	7.5	23.5	2.0	2.9
36-41 (n=23)	56.6	2.6	30.4	8.7	4.3
Education						0.131
Middle school (n=34)	73.5	2.3	14.7	5.9	5.9
High school and secondary school (n=48)	64.5	4.4	31.3	2.1	2.1
Postsecondary (n=125)	69.6	9.8	30.4	0.0	0.0
Undergraduate (n=165)	41.5	13.4	26.7	3.0	1.8
Postgraduate (n=16)	37.4	1.3	31.3	31.3	0.0
Gravidity						0.636
0-1 (n=166)	72.9	11.6	24.1	1.2	1.8
2-4 (n=214)	65.4	34.6	30.4	2.8	1.4
5-7 (n=8)	75.0	0.5	25.0	0.0	0.0
Parity						0.051
0 (n=224)	73.7	15.2	24.1	0.9	1.3
≥1 (n=164)	62.2	16.0	32.3	3.7	1.8
Iron-containing supplement						0.129
Untaken	65.7	21.1	29.7	2.1	2.5
Taken	73.8	10.1	24.2	2.0	0.0

Items	Total(n=388)	Normal(n=267)	Iron deficiency			P
Items	Total(n=388)	Normal(n=267)	ID (n=107)	IDE (n=8)	IDA (n=6)	P
Pre-pregnancy BMI	22.8±3.8	22.8±3.9	22.7±3.5	23.3±2.5	20.0±2.1	0.322
Body fat/%	32.9±6.1	33.1±6.0	32.5±6.3	33.4±5.4	28.3±3.8	0.239
Waist-hip ratio	0.89±0.05	0.89±0.05	0.89±0.06	0.89±0.05	0.84±0.03	0.173
Serum ferritin/(μg/dL)	50.4±35.3	64.6±33.8	20.7±6.2	9.1±3.6	5.2±1.8	< 0.001
Hemoglobin/(g/L)	131.2±10.3	132.4±9.5	130.7±9.2	121.4±7.3	98.0±7.5	< 0.001
Serum iron/(μg/dL)	117.9±38.3	122.4±35.7	116.7±35.8	49.7±11.8	28.0±12.4	< 0.001
TIBC(μg/dL)	325.5±49.7	310.7±42.7	349.0±41.0	397.5±38.4	468.7±17.8	<0.001
TS/%	33.6±12.9	36.2±12.5	30.3±10.1	11.0±3.0	5.2±2.3	< 0.001

Items	Dietary pattern
Items	Balanced	High protein and whole grains	Refined grains
Red meat	0.62	0.46	0.46
Poultry	1.17	0.14	-0.31
Seafood and aquatic products	0.18	0.69	0.16
Organ	0.61	0.25	-0.20
Egg	0.01	0.17	-0.49
Vegetables	0.82	-0.02	0.31
Fruits	1.03	0.01	0.13
Dairy	1.05	0.23	0.22
Soys	0.14	0.76	-0.20
Refined grains	0.15	0.25	0.75
Whole grains and legumes	0.11	0.76	0.03
Contribution rate/%	17.49	15.82	11.34
Accumulated contributionrate/%	17.49	33.30	44.64

Items	OR	95%CI	P
Age	0.96	(0.94, 0.97)	< 0.001
Balanced dietary pattern	0.81	(0.66, 1.00)	0.054
Multiparity	3.90	(1.81, 8.42)	0.001
Iron containing supplement	1.34	(0.65, 2.77)	0.429
Multiparty × iron containing supplement	0.27	(0.09, 0.83)	0.022