ライフサイエンスコーパス: prepregnancy

1 ation results in mothers who were overweight prepregnancy.

2 Prepregnancy adherence to healthful dietary patterns is

3 Prepregnancy adherence to several dietary patterns was n

4 We aimed to assess prepregnancy adherence to the alternate Healthy Eating I

5 This study aimed to assess usual prepregnancy adherence to well-known dietary patterns an

6 Maternal prepregnancy adiposity may influence child adiposity bey

7 Prepregnancy adiposity was associated with offspring gro

8 al health, lifestyle, and diet were assessed prepregnancy and at 11 and 34 wk of gestation.

9 The following cardiovascular parameters prepregnancy and at 20 weeks gestation were associated w

10 regnancy LDL-C levels compared with paternal prepregnancy and parental concurrent LDL-C levels in ass

11 7 y, we compared associations with maternal prepregnancy and postpartum BMI z scores and with patern

12 station (P = 0.003), and weight gain between prepregnancy and the postpartum examination (P = 0.03).

13 s the scope of midwifery practice, including prepregnancy, antenatal, labour, birth, and post-partum

14 Among prepregnancy antidepressant users, the authors compared

15 Within prepregnancy antidepressant users, the relative risk for

16 Compared with prepregnancy baseline, within-individual analyses indica

17 ry for the prevention of SSI in obese women (prepregnancy BMI >/=30) who had received standard intrav

18 gnancy BMI (in kg/m(2)) <24.0] and 12 obese (prepregnancy BMI >30.0) mothers and their exclusively br

19 fects resulted in null associations for both prepregnancy BMI (beta = 0.03 units, 95% CI: -0.01, 0.07

20 ed in multivitamin users regardless of their prepregnancy BMI (HR: 0.83; 95% CI: 0.73, 0.95), with th

21 asting HM samples were collected from 18 NW [prepregnancy BMI (in kg/m(2)) <24.0] and 12 obese (prepr

22 tconception multivitamin use in women with a prepregnancy BMI (in kg/m(2)) <25 was associated with re

23 ostpartum, 68 lactating Swedish women with a prepregnancy BMI (in kg/m(2)) of 25-35 were randomly ass

24 ffspring were 3 years of age, using parental prepregnancy BMI (measured as weight in kilograms divide

25 t, higher paternal BMI (P < 0.001), maternal prepregnancy BMI (P < 0.001), and lower family socioecon

26 ger maternal age (P = 0.02), higher maternal prepregnancy BMI (P < 0.001), higher maternal weight gai

27 m PPWR and the percentage body fat varied by prepregnancy BMI (P-interaction </= 0.06); excessive GWG

28 Proportions mediated through prepregnancy BMI (per 1-kg/m(2) increase) were 32% and 2

29 Maternal prepregnancy BMI (SD score) was positively associated wi

30 Prepregnancy BMI (weight in kilograms divided by height

31 - and 2-hour OGTT were positively related to prepregnancy BMI and blood pressure; HDL cholesterol was

32 C-reactive protein was positively related to prepregnancy BMI and diastolic blood pressure (P <0.05).

33 ers were predicted by interacting effects of prepregnancy BMI and excessive GWG.

34 With generalized estimating equations, prepregnancy BMI and gestational weight gain had similar

35 Maternal prepregnancy BMI and GWG, including period-specific GWG,

36 The positive relation between maternal prepregnancy BMI and offspring bone mass is likely due t

37 To examine the association between prepregnancy BMI and severe maternal morbidity.

38 bust standard errors, adjusting for maternal prepregnancy BMI and sociodemographic and perinatal fact

39 Mean +/- SD prepregnancy BMI and total GWG were 25.6 +/- 5.8 (42% of

40 For each birth, maternal prepregnancy BMI and WC were measured at year 0 (baselin

41 These findings suggest that prepregnancy BMI as a single mediator contributes substa

42 ated with excessive GWG, was estimated for 2 prepregnancy BMI examples.

43 d were also noted in women who had a healthy prepregnancy BMI for both pregnancies.

44 ir intentions to breastfeed, women with high prepregnancy BMI had psychosocial characteristics associ

45 sity in offspring during childhood, but high prepregnancy BMI has a stronger influence than either ge

46 to formally quantify the mediating effect of prepregnancy BMI in these associations.

47 For a woman with prepregnancy BMI of 22, excessive GWG was associated wit

48 PWR (P < 0.001); however, for a woman with a prepregnancy BMI of 30, excessive GWG was associated wit

49 Girls whose mothers have a high prepregnancy BMI seem most affected.

50 Prepregnancy BMI was associated with confidence in (P <

51 Prepregnancy BMI was distributed as follows: underweight

52 veloped for women with low, normal, and high prepregnancy BMI were shown to fit the original data.

53 atients matched to non-case patients by age, prepregnancy BMI, and race/ethnicity.

54 nant women in Washington State, low and high prepregnancy BMI, compared with normal BMI, were associa

55 in addition to national recommendations for prepregnancy BMI, gestational weight gain, and postpartu

56 ted positive and independent associations of prepregnancy BMI, GWG, and percentile change in early ch

57 Independent of maternal prepregnancy BMI, HM insulin was positively associated w

58 weight gain during pregnancy, regardless of prepregnancy BMI, is directly related to offspring adipo

59 were adjusted for age at outcome assessment, prepregnancy BMI, marital status and insurance at delive

60 Prepregnancy weight, prepregnancy BMI, systolic and diastolic blood pressure,

61 A set of prepregnancy BMI-dependent mathematical models that pred

62 oys separately, taking into account maternal prepregnancy BMI.

63 al adiposity but only in women with a normal prepregnancy BMI.

64 , adjusting for major risk factors including prepregnancy BMI.

65 GDM and HDP and proportions mediated through prepregnancy BMI.

66 /obesity risk at 7 y, adjusting for maternal prepregnancy BMI.

67 ate of weight gain decreased with increasing prepregnancy BMI.

68 greater long-term PPWR in mothers with lower prepregnancy BMI.

69 e; HDL cholesterol was negatively related to prepregnancy BMI; C-reactive protein was positively rela

70 ely), adjusting for age; maternal age, race, prepregnancy BMI; parity; smoking during pregnancy; and

71 cal bacteria of 91 pregnant women of varying prepregnancy BMIs and gestational diabetes status and th

72 Smoking (never, light, heavy), stratified by prepregnancy body mass index (BMI (weight (kg)/height (m

73 we examined the association of (i) maternal prepregnancy body mass index (BMI) and (ii) gestational

74 We estimated associations of maternal prepregnancy body mass index (BMI) and gestational weigh

75 authors examined the association of maternal prepregnancy body mass index (BMI) and gestational weigh

76 e estimated the association between maternal prepregnancy body mass index (BMI) and the risk of still

77 They were grouped according to prepregnancy body mass index (BMI) in underweight (BMI<1

78 ctives were to determine whether 1) maternal prepregnancy body mass index (BMI) is associated with so

79 luenced by perinatal determinants, including prepregnancy body mass index (BMI), gestational weight g

80 Within each maternal prepregnancy body mass index (BMI, kg/m(2)) stratum, the

81 tes and included an interaction term between prepregnancy body mass index (BMI; in kg/m(2)) and GWG.

82 k (n=27) of obesity on the basis of maternal prepregnancy body mass index (BMI; in kg/m(2)).

83 6, 1.25) for each unit increment in maternal prepregnancy body mass index (BMI; in kg/m(2)).

84 ge (> or =19.8 to < or =26.0), or high (>26) prepregnancy body mass index (BMI; in kg/m2).

85 y comparing the association between maternal prepregnancy body mass index (BMI; measured as weight in

86 s examined the associations between parental prepregnancy body mass index (BMI; weight (kg)/height (m

87 08), we examined the association of maternal prepregnancy body mass index (BMI; weight (kg)/height (m

88 However, the association was modified by prepregnancy body mass index (BMI; weight (kg)/height (m

89 2.1, 95% CI: 1.0, 4.2), and higher maternal prepregnancy body mass index (body mass index of 25-29 v

90 rent and adjusted for maternal age, maternal prepregnancy body mass index (kilograms per meter square

91 M2.5) and its joint effect with the mother's prepregnancy body mass index (MPBMI) on COWO remain uncl

92 ing evidence demonstrates that both maternal prepregnancy body mass index (mppBMI) and gestational we

93 he relation between gestational glycemia and prepregnancy body mass index (ppBMI) with offspring grow

94 els less than 30 nmol/L after adjustment for prepregnancy body mass index (weight (kg)/height (m)(2))

95 al hazards models adjusted for maternal age, prepregnancy body mass index (weight (kg)/height (m)(2))

96 95% confidence intervals, adjusting for age, prepregnancy body mass index (weight (kg)/height (m)(2))

97 and triglycerides in the association between prepregnancy body mass index (weight (kg)/height (m)2) a

98 Prepregnancy body mass index [BMI (in kg/m(2))], gestati

99 echnology (ART) with preterm birth varies by prepregnancy body mass index and 2) whether the associat

100 l and race/ethnic-specific relations between prepregnancy body mass index and both preterm birth and

101 potential confounding factors, particularly prepregnancy body mass index and maternal diabetes, incr

102 ledge, the first representative estimates of prepregnancy body mass index and weight gain during preg

103 When stratified by prepregnancy body mass index category, exercise was asso

104 rity, no history of breastfeeding and higher prepregnancy body mass index in adjusted models.

105 Prepregnancy body mass index modified this relation.

106 Compared with a prepregnancy body mass index of 22, a body mass index of

107 Prepregnancy body mass index was a strong predictor of i

108 In addition, the interaction of group and prepregnancy body mass index was also evaluated, and no

109 from mothers with different food choices and prepregnancy body mass index were determined with two ta

110 in the full cohort and for maternal smoking, prepregnancy body mass index, and gestational weight gai

111 After adjustment for age, ethnicity, prepregnancy body mass index, and intervention group, ch

112 maternal age, height, education, ethnicity, prepregnancy body mass index, and plasma folate, vitamin

113 l adjustment for family history of diabetes, prepregnancy body mass index, and weight gain during pre

114 ng increased significantly with increases in prepregnancy body mass index, current body mass index, p

115 models and adjusted for covariates including prepregnancy body mass index, gestational weight gain, m

116 x, maternal demographics, parity, insurance, prepregnancy body mass index, pregnancy complications, a

117 A priori covariates included maternal prepregnancy body mass index, pregnancy weight gain, and

118 Adjustment for prepregnancy body mass index, prepregnancy physical acti

119 nal age, birth weight, maternal age, parity, prepregnancy body mass index, smoking, hypertension, dia

120 ession analyses for women in 3 categories of prepregnancy body mass index.

121 rs, gestational age at blood collection, and prepregnancy body mass index.

122 ection in neonates born to mothers with high prepregnancy body mass index.

123 se in studying pregnant women with different prepregnancy body mass indexes, different gestational we

124 Maternal prepregnancy body size was differently associated with G

125 examined the associations between change in prepregnancy body-mass index (BMI) from the first to the

126 ere not significantly different from that at prepregnancy, but urinary calcium decreased to 1.87+/-1.

127 This study examined prepregnancy cardiometabolic risk factors and gestationa

128 The authors measured prepregnancy cardiometabolic risk factors and performed

129 Pregnancies were free of prepregnancy chronic disease or previous GDM.

130 protective dose-response association between prepregnancy consumption of a Mediterranean-style dietar

131 ed mortality and morbidity warrant extensive prepregnancy counseling and centralization of care.

132 Suggestive associations included maternal prepregnancy diabetes (HR = 1.33, 95% CI: 0.89, 1.98) an

133 Prepregnancy diabetes and obesity have been identified a

134 ter controlling for changes in maternal age, prepregnancy diabetes mellitus, preterm preeclampsia, mu

135 ES; RR = 2.02; 95% CI: 1.28, 3.18), maternal prepregnancy diabetes or gestational diabetes (RR = 1.54

136 n was used to assess the association between prepregnancy diabetes or gestational diabetes and perina

137 the total amount and the type and source of prepregnancy dietary fats are related to risk of GDM.

138 Prepregnancy dietary pattern adherence scores were compu

139 Prepregnancy dietary pattern scores were computed as the

140 We investigated associations between prepregnancy dietary patterns and risk of HDPs.

141 ing dyslipidemia is associated with maternal prepregnancy dyslipidemia in excess of measured lifestyl

142 We investigated how maternal prepregnancy fat distribution, described by waist circum

143 d the increase is positively correlated with prepregnancy fatness, and 3) energy expenditure in activ

144 d data, including TTP, maternal age, parity, prepregnancy height and weight, maternal occupational st

145 Later ICP was more common in women with prepregnancy hepatitis C (OR 5.76; 1.30-25.44; P = 0.021

146 Prepregnancy history of depression was a risk factor for

147 A prepregnancy history of infertility was reported by 5,49

148 increased significantly with the recency of prepregnancy hospitalizations, number of previous hospit

149 Prepregnancy human and guinea pig cytomegalovirus immuni

150 omalous, singleton, term pregnancies with no prepregnancy hypertension or diabetes.

151 Women with preeclampsia, prepregnancy hypertension, or diabetes were excluded.

152 essing maternal educational immunity through prepregnancy immunization programs has potential for imp

153 -born infants born to mothers who received a prepregnancy immunization, are blunted.

154 nment--may explain birth weight and suggests prepregnancy influences.

155 Higher prepregnancy intakes of animal fat and cholesterol were

156 e while pregnant compared with an equivalent prepregnancy interval was similar to that seen in pregna

157 Prepregnancy LCD scores were calculated from validated f

158 g LDL-C levels were associated with maternal prepregnancy LDL-C levels after adjustment for family re

159 Maternal prepregnancy LDL-C levels compared with paternal prepreg

160 Maternal prepregnancy LDL-C levels explained 13% of the variation

161 ts who had been exposed to elevated maternal prepregnancy LDL-C levels were at a 3.8 (95% CI, 1.5-9.8

162 sting for age, race, parental education, and prepregnancy lifestyle and CVD risk factors, preterm del

163 ether this risk remains after adjustment for prepregnancy lifestyle and CVD risk factors.

164 A prepregnancy low-carbohydrate dietary pattern with high

165 sitively associated with GDM risk, whereas a prepregnancy low-carbohydrate dietary pattern with high

166 o prospectively examine the association of 3 prepregnancy low-carbohydrate dietary patterns with risk

167 fferences within UCB monocytes stratified by prepregnancy maternal body mass index.

168 Prepregnancy maternal obesity is associated with adverse

169 High prepregnancy maternal weight gain and long interpregnanc

170 es substantially to the total effects of the prepregnancy Mediterranean diet on GDM and HDP risk.

171 direct, and natural indirect effects of the prepregnancy Mediterranean diet on incident GDM and HDP

172 widely from woman to woman depending on her prepregnancy nutrition, genetic determinants of fetal si

173 for maternal educational level, parity, and prepregnancy obesity (adjusted odds ratio, 2.36; 95% CI,

174 997-2009) to examine the association between prepregnancy obesity (body mass index, measured as weigh

175 rted by 33% of women and was associated with prepregnancy obesity (OR: 1.56; 95% CI: 1.07, 2.29), old

176 ored whether there is an association between prepregnancy obesity and periodontitis among pregnant fe

177 There is a positive association between prepregnancy obesity and periodontitis among pregnant fe

178 Prepregnancy obesity and serum leptin are strong risk fa

179 usted odds ratio for the association between prepregnancy obesity and spina bifida was 1.48 (95% conf

180 We examined the associations between prepregnancy obesity and the risks of myocardial infarct

181 lmer et al., particularly their finding that prepregnancy obesity modifies the relationship between l

182 However, gestational FPG and prepregnancy obesity status interacted significantly for

183 justment for confounders, including maternal prepregnancy obesity status.

184 ion of risk factors such as hypertension and prepregnancy obesity that disproportionately affect Afri

185 In apparently healthy women of fertile age, prepregnancy obesity was associated with increased risks

186 Prepregnancy obesity was statistically significantly ass

187 race and ethnicity, smoking, stress, atopy, prepregnancy obesity) showed that increased PM2.5 exposu

188 adjusted for maternal age, race, education, prepregnancy obesity, atopy, and smoking status identifi

189 nd maternal receipt of public assistance and prepregnancy obesity, higher prenatal PAH exposures were

190 ger associations were observed with maternal prepregnancy obesity.

191 Measurements were made before conception (prepregnancy), once during each trimester of pregnancy (

192 f women who gave birth, 15.2% (n = 100) with prepregnancy or gestational diabetes and 8.5% (n = 886)

193 Prepregnancy or gestational diabetes was independently a

194 Exclusion criteria were BMI <30.0 or >39.9, prepregnancy or gestational diabetes, age <18 y, multipl

195 r the first birth, by women with and without prepregnancy or prenatal psychiatric hospitalization.

196 Maternal prepregnancy overweight (OR: 1.19, 95% CI: 1.03-1.38) an

197 Prepregnancy overweight modified this effect.

198 ultivitamin use and PTBs varied according to prepregnancy overweight status (P-interaction = 0.07).

199 s a child, education and income as an adult, prepregnancy overweight, and prenatal smoking.

200 simultaneous mediation by and adjustment for prepregnancy overweight.

201 .7+/-21.2 mg/cm3 from 162.9+/-25.0 mg/cm3 at prepregnancy (P < 0.001).

202 supplement use (compared with no use) in the prepregnancy period through the first trimester and asth

203 for race/ethnicity, marital status, parity, prepregnancy physical activity, and income in a multiple

204 Adjustment for prepregnancy body mass index, prepregnancy physical activity, and prepregnancy smoking

205 ical cords of infants born to normal-weight (prepregnancy [pp] BMI 21.1 +/- 0.3 kg/m(2); n = 15; NW-M

206 Few data sets contain prepregnancy, pregnancy, and childhood information.

207 of cardiac events was compared during equal prepregnancy, pregnancy, and postpartum intervals (40 we

208 Reported prepregnancy problems in these gravidas included atrial

209 proportion of the incidence attributable to prepregnancy psychiatric morbidity.

210 to prevent anaphylaxis in pregnancy through prepregnancy risk assessment and risk reduction strategi

211 ific defects or lesions, imaging techniques, prepregnancy risk assessment,and can manage these patien

212 In patients with greater prepregnancy SCr and/or drug-treated hypertension during

213 In patients with prepregnancy serum creatinine (SCr) >150 micromol/L, a t

214 The r-AKI and control groups had similar prepregnancy serum creatinine measurements (0.70+/-0.20

215 s index, prepregnancy physical activity, and prepregnancy smoking attenuated the associations slightl

216 ox proportional hazards model, adjusting for prepregnancy sociodemographic, lifestyle, reproductive,

217 Prepregnancy Tdap vaccination significantly increases ma

218 during the periconceptional period (1 month prepregnancy through the third pregnancy month) were div

219 ion of calcium increased from 32.9+/-9.1% at prepregnancy to 49.9+/-10.2% at T2 and 53.8+/-11.3% at T

220 calcium increased from 4.32+/-2.20 mmol/d at prepregnancy to 6.21+/-3.72 mmol/d at T3 (P < 0.001), bu

221 at and long-term PPWR (change in weight from prepregnancy to 7 y postpartum)], adjusting for covariat

222 2 weeks preconception and during gestation), prepregnancy trained (housed with running wheels for 2 w

223 Levels of prepregnancy underweight for India are almost seven perc

224 n; they then decreased but did not return to prepregnancy values until 300 d after parturition.

225 ncrease the percentages of women who reached prepregnancy weight (n = 261; 45.3% compared with 35.3%;

226 Greater maternal prepregnancy weight and GWG up to 36 weeks of gestation

227 We aimed to examine associations of prepregnancy weight and GWG with maternal body mass inde

228 The mother's periodontal parameters, age, prepregnancy weight and height and body mass index (BMI)

229 education, parity, stress, passive smoking, prepregnancy weight and height, and infant's sex.

230 adjusted for parity, fetal sex, and maternal prepregnancy weight and height.

231 ation to birth outcomes and whether maternal prepregnancy weight and infant sex modified the associat

232 Data on prepregnancy weight and the temporal course of GWG were

233 significant effect on the odds of achieving prepregnancy weight at 12 mo postpartum (n = 331; 35.4%

234 ease the proportion of women who returned to prepregnancy weight by 12 mo postpartum.

235 The use of measured prepregnancy weight in tests of the effect on newborn si

236 nalyzed protein intake as grams per kilogram prepregnancy weight per day.

237 l second-trimester urinary arsenic, maternal prepregnancy weight through self-report, and birth outco

238 When examined in more detail, greater prepregnancy weight was associated with greater offsprin

239 mates from random-effects multilevel models, prepregnancy weight was positively associated with all o

240 Maternal prepregnancy weight was self-reported, and current weigh

241 Maternal weight gain during pregnancy and prepregnancy weight were ascertained from medical record

242 ciation of gestational weight gain (GWG) and prepregnancy weight with offspring adiposity and cardiov

243 .1 years; Hispanic, 81.6%; mean weight above prepregnancy weight, 7.8 kg; mean months post partum, 5.

244 for maternal age, race, education, smoking, prepregnancy weight, gestational age at blood draw, and

245 The objective was to examine how prepregnancy weight, gestational weight gain, postpartum

246 Prepregnancy weight, prepregnancy BMI, systolic and dias

247 >88 cm and weight change as current weight - prepregnancy weight.

248 ults support initiatives aimed at optimizing prepregnancy weight.

249 , and TMEM18 were positively associated with prepregnancy weight.

250 ferent results than does the use of recalled prepregnancy weight.

251 -gain recommendations in women with a normal prepregnancy weight.

252 (wrist circumference at week 37, mm)+ 0.10 (prepregnancy weight.kg)-6.56 (r2 = 0.89).