PLoS ONEplosplosonePLOS ONE1932-6203Public Library of ScienceSan Francisco, CA USA10.1371/journal.pone.0160704PONE-D-16-03422Research ArticleBiology and life sciencesBiochemistryLipidsFatsBiology and life sciencesAnatomyCardiovascular anatomyBlood vesselsRetinal vesselsMedicine and health sciencesAnatomyCardiovascular anatomyBlood vesselsRetinal vesselsBiology and life sciencesAnatomyOcular systemOcular anatomyRetinal vesselsMedicine and health sciencesAnatomyOcular systemOcular anatomyRetinal vesselsBiology and life sciencesNutritionDietMedicine and health sciencesNutritionDietMedicine and health sciencesWomen's healthMaternal healthPregnancyMedicine and health sciencesWomen's healthObstetrics and gynecologyPregnancyPhysical sciencesChemistryChemical compoundsOrganic compoundsCarbohydratesPhysical sciencesChemistryOrganic chemistryOrganic compoundsCarbohydratesBiology and life sciencesNutritionDietFoodMedicine and health sciencesNutritionDietFoodMedicine and health sciencesEndocrinologyEndocrine disordersDiabetes mellitusMedicine and health sciencesMetabolic disordersDiabetes mellitusMedicine and health sciencesEndocrinologyEndocrine disordersDiabetes mellitusType 2 diabetesDiet and type 2 diabetesMedicine and health sciencesMetabolic disordersDiabetes mellitusType 2 diabetesDiet and type 2 diabetesThe Impact of Macronutrients on Retinal Microvasculature among Singapore Pregnant Women during the Mid-Late GestationMaternal Nutrition and Retinal MicrovasculatureLiLing-Jun12OngPeng Guan1ColegaMarjorelee T.3HanChad Yixian4ChenLing Wei567Man Eyn KiddRyan1LamoureuxEcosse12GluckmanPeter5KwekKenneth8ChongYap Seng39SawSeang Mei110GodfreyKeith M.11WongTien Yin12*Chong Foong-FongMary356*GUSTO study group¶Singapore Eye Research Institute, Singapore National Eye Centre, Singapore, SingaporeDUKE-NUS Graduate Medical School, Singapore, SingaporeSingapore Institute for Clinical Sciences, Growth, Development & Metabolism, Singapore, SingaporeDepartment of Nutrition and Dietetics, Flinders University of South Australia, Adelaide, South Australia, AustraliaSingapore Institute for Clinical Sciences, Agency for Science, Technology and Research, Singapore, SingaporeDepartment of Paediatrics, Yong Loo Lin School of Medicine, National University of Singapore and National University Health System, Singapore, SingaporeKhoo Teck Puat- National University Children’s Medical Institute, National University Health System, Singapore, SingaporeKK Women’s and Children’s Hospital, Singapore, SingaporeDepartment of Obstetrics and Gynecology, Yong Loo Lin School of Medicine, National University of Singapore, Singapore, SingaporeSaw Swee Hock School of Public Health, National University of Singapore, Singapore, SingaporeMedical Research Council Lifecourse Epidemiology Unit and NIHR Southampton Biomedical Research Centre, University of Southampton and University Hospital Southampton NHS Foundation Trust, Southampton, United KingdomStaigerHaraldEditorMedical Clinic, University Hospital Tuebingen, GERMANY
The authors have declared that no competing interests exist.
Conceptualization: L-JL MCF-F.
Data curation: LWC MTC CYH PGO.
Formal analysis: L-JL PGO CYH MCF-F.
Methodology: L-JL SMS TYW MCF-F.
Resources: PG KMG YSC KK.
Software: TYW.
Supervision: TYW MCF-F.
Validation: TYW CYH.
Writing - original draft: L-JL MCF-F.
Writing - review & editing: L-JL CYH LWC RMEK EL PG KK YSC SMS KMG TYW MCF-F.
¶ Membership of the GUSTO study group is listed in the Acknowledgments.
* E-mail: mary_chong@sics.a-star.edu.sg (MCFF); wong.tien.yin@snec.com.sg (TYW)10820162016118e0160704251201622720162016Li et alThis is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.Background
Imbalanced macronutrient intakes can induce impairment of endothelial and vascular function, and further lead to metabolic and cardiovascular disease. However, little is known about the influence of such diets on endothelial and vascular dysfunction in pregnant women, even though high-fat diet is a known risk for pregnancy complications such as gestational diabetes and pre-eclampsia.
Objective
We aimed to assess the association between maternal macronutrient intakes (protein, fat and carbohydrates), dietary quality and retinal microvascular changes in a multi-ethnic Asian mother-offspring cohort.
Methods
Pregnant women (n = 614) with singleton pregnancies were recruited during their first trimester from June 2009 to Sep 2010. Maternal diet quality and macronutrient intakes, expressed as a percentage of total energy during pregnancy, were ascertained using 24 hr recalls and 3 d food diaries at 26–28 weeks gestation. Retinal examination was completed at the same clinic visit. Dietary quality was assessed and scored using the Health Eating Index in Asian Pregnant women (HEI-AP), while macronutrients intakes ware expressed as percentages of total energy and further log transformed for analysis. Associations were examined cross-sectionally by substitution models with the use of multiple linear regression.
Results
In adjusted model, each 20 points decrease in HEI-AP score was associated with a significant increase of 1.70 μm (p<0.05) in retinal venular calibre. Each 0.1 log increase in percentage of total fat intake was associated with a significant increment of 1.84 μm (p<0.05) in retinal venular caliber. Additionally, each 0.1 log increase in percentage of mono-unsaturated fat intake was associated with an increment of 1.84 μm (p<0.01) in retinal venular caliber.
Conclusions
In this cross-sectional study, we found that women with higher fat and lower protein intakes, and lower diet quality tended to have wider retinal venular caliber, which is suggestive of suboptimal microvasculature.
National Medical Research Counsil, SingaporeNMRC/TCR/004-NUS/2008ChongYap SengNational Medical Researc Council, SingaporeNMRC/TA/0027/2014Lingjun LiNational Medical Research Counsil, SingaporeNMRC/CG/SERI/2010 & NMRC/STaR/0003/2008WongTien YinThis study is under Translational Clinical Research (TCR) Flagship Programme on Developmental Pathways to Metabolic Disease, NMRC/TCR/004-NUS/2008 funded by the National Research Foundation (NRF) and administered by the National Medical Research Council (NMRC), Singapore. Dr. Ling-Jun Li received funding from the Singapore Ministry of Health’s National Medical Research Council (NMRC/TA/0027/2014). Prof. Tien-Yin Wong is supported by the National Medical Research Council, Singapore, NMRC/CG/SERI/2010, and NMRC/STaR/0003/2008. Professor Keith M. Godfrey is supported by the National Institute for Health Research through the NIHR Southampton Biomedical Research Centre.Data AvailabilityData are available upon request because data request for analysis must be assessed and approved by the executive committee of the GUSTO study and administered by the main GUSTO study team of data management, which is a third-party source. Any matter related to data request, please contact: Dr. Shirong Cai, research fellow for GUSTO study group at obgcais@nus.edu.sg.Introduction
Macronutrients, i.e. protein, fat and carbohydrates, supply energy to meet the body’s need for specific physiological function [1,2]. The imbalance in the proportions of macronutrient intakes such as a high-fat diet has been shown to be associated with long-term increased risk of metabolic disorders [3–5] and cardiovascular diseases [6–8]. Substantial evidence from animal experiments [9–11] and human studies [12–15] has suggested that impairment of endothelial and vascular function, resulting from either high-fat diets or advanced glycation end products, could be the major underlying mechanism. In recent decades, dietary macronutrient intakes have also been found to be associated with pregnancy complications such as gestational diabetes [16–19] and pre-eclampsia [20–22], possibly via the pathways of endothelial dysfunction, inflammatory activation and oxidative stress [22,23]. Whether such diets during pregnancy also impact on the microvasculature, a surrogate marker of endothelial and vessel function in vivo, is unknown.
With the help of recent technological advancement, microvasculature in vivo has provided a valuable “window” through which clinicians are able to monitor endothelial function and inflammation in human subjects in a non-invasive manner [24]. A series of retinal vascular abnormalities (e.g. retinal arteriolar narrowing, retinal venular widening, higher length-to-diameter ratio and more tortuous retinal arterioles) have been repeatedly proven to be associated with biomarkers linked to endothelial dysfunction, inflammation and dyslipdemia [25–29]. In adults and children, studies have shown that suboptimal dietary intakes such as high sugar, low fibre and low fish oil intakes were associated with retinal vascular changes (e.g. narrower retinal arterioles, wider retinal venules and lower fractal dimension), which are consistent to the abnormalities mentioned above [30–33].
Therefore, we aimed to study the association between maternal macronutrient intakes and maternal retinal microvasculature in a cohort of 614 pregnant women. We hypothesized that pregnant women with high-fat diet and poorer diet quality represented by lower dietary quality indexes were more susceptible to microvascular abnormality such as retinal arteriolar narrowing or retinal venular widening.
MethodsStudy population and design
This is a hospital-based, cross-sectional observational study. Women with singleton pregnancies were recruited during their first trimester in the on-going birth cohort study, the Growing Up in Singapore Towards Healthy Outcomes (GUSTO), from June 2009 to Sep 2010. Pregnant women who were Singaporean residents aged 18 years and above, attending either KK Women’s and Children’s hospital (KKH) or National University Hospital (NUH), and intending to deliver and reside in Singapore for the next 5 years were included. The details of the study methodology have been reported elsewhere [34].
Among 1163 women recruited in this cohort, 614 subjects completed both retinal photography and food dietary questionnaire during mid-late gestation (26–28 weeks’ pregnancy). The reason of the subset being chosen was due to the logistic issue that only participants from KKH were able to get access to retinal examination.
Ethics Statement
This study was approved by both SingHealth Centralized Institutional Review Board and the National Health Group’s Domain Specific Review Board, and it was conducted according to the tenets of the Declaration of Helsinki. Written informed consent in 3 copies were obtained from participants prior to any examination. Among these 3 copies, 1 was kept by the mothers, 1 was for the study principal investigator and another was kept at the research site. SingHealth Centralized Institutional Review Board had approved such consent procedure before this study was conducted.
Dietary AssessmentMacronutrients Assessment
Dietary intakes were ascertained with the use of a 24 hour recall during the 26–28 week’ gestation visit [35–37]. A 5-stage, multiple-pass interviewing technique was applied in the 24 hour recall questionnaire conducted by trained clinical staff [38]. To assist women in quantifying their food and beverage intake, visual aids such as standardized household measuring utensils and food pictures of various portion sizes were presented. All subjects were familiarized with the food pictures and then were led through the interview by the trained interviewer. The multiple-pass assessment consists of 5 steps: 1) the quick list, which is an uninterrupted listing by the subjects of foods and beverages consumed; 2) the forgotten foods list, which queries the subject on categories of foods that have been documented as frequently forgotten; 3) a time and occasion at which foods were consumed; 4) the detailed cycle, which elicits descriptions of foods and amounts eaten aided by the interactive use of the food pictures and measuring guides; and 5) the final probe review. The women were also asked to complete a 3-day food diary at home, following the visit. These were returned to the clinic staff at the following visit. Only a subset of women (n = 835) completed and returned the diaries. Dietary data from the 3-day food diaries was used to validate the dietary data obtained from the 24 hr recalls. Results from 24 hour recalls relating to health outcomes and those from food diaries relating to similar health outcomes have been shown to be comparable [36]. Such methods of assessing dietary data have been widely published and accepted [39–41].
Food diaries were returned at the next clinic visit and analyses of the dietary records were performed with the use of nutrient analysis software (Dietplan, Forestfield Sofrware, U.K.), or the dietary records composition database derived on locally available foods [36,42]. Energy-adjusted macronutrient intakes were expressed as percentage of total energy, such as percentage fat of total energy, percentage carbohydrates of total energy etc. Different fat types such as saturated fat, mono-unsaturated fat (MUFA) and poly-unsaturated fat intakes (PUFA) were also expressed as % of total energy. The macronutrient and fat types analyses in this study were based on data from the 24 hour recalls.
Diet quality
is measured by scoring food patterns in terms of how closely they align with national dietary guidelines and how diverse the variety of healthy choices is within core food groups or equivalent international groupings [43]. The healthy eating index for Asian pregnant women (HEI-AP) was developed and validated locally to examine dietary quality in pregnant women [44]. It was adapted from both the Healthy Eating Indices (HEI) [45–47] and Alternative Healthy Eating Index for Pregnancy (AHEI-P) [48] and modified accordingly to recommendations from the Singapore dietary guidelines for pregnant women [49]. In brief, the HEI-AP consists of 11 components including total fruit, whole fruit, total vegetables, dark green leafy and orange vegetables, total rice and alternatives, whole grains, dairy, total protein foods, use of antenatal supplements, total fat and saturated fat. Out of the 11 components, there are 8 food-based components (4-adequacy of food groups, 4–quality of food groups), 2 nutrient-based components to reflect nutrients to be taken in moderation, and 1 to assess adherence to antenatal supplements. Minimum and maximum scores range between 0 and 5 points for the first four components, and range between 0 and 10 points for the rest of the seven components. The total raw score is up to 90 and scaled up to 100 as per the referenced HEI [44] (S1 Fig). By using a density basis of recommended serve size per 1000kcal, each individual’s reported energy intake was adjusted for energy intake and the diet quality score was more comparable between individuals [44]. For each woman, a diet quality score is calculated. The higher the score, the closer adherence the diet is to guidelines and thus reflects better quality of the diet. Further details of the HEI- AP can be found in Han et al, 2015 [44].
Retinal Photography and Measurements of Retinal Vascular Parameters
Retinal photography and measurements of retinal vascular parameters were performed at the same clinic visit where 24 hr food recall data were collected. Right eye retinal photographs were performed without pharmacological pupil dilation using a 45° non-mydriatic retinal camera (Canon CR-1, 40D SLR digital-retinal camera backing, Canon Inc., Japan). All retinal photographs were centered on the optic disc and then assessed by a trained grader using a semi-automated computer-based program (Singapore I Vessel Assessment [SIVA] version 3.0, Singapore Eye Research Institute, Singapore). All vessels located in zone C which was marked in SIVA software by 0.5–2.0 optic disc diameter away from the optic disc margin were recruited for calibration (Fig 1). Retinal vascular caliber, represented as central retinal arteriolar equivalent (CRAE) and central retinal venular equivalent (CRVE), was assessed. Morphological differences between normal and narrow CRVE among our subjects are shown in Fig 2.
10.1371/journal.pone.0160704.g001
Image of SIVA grading platform.
Retinal microvasculature assessment on the grading platform. A screenshot of a computer-assisted program for measurement of new geometrical retinal vascular parameters from retinal fundus photograph. Zone C is marked in SIVA software by 0.5 to 2.0 optic disc diameter away from the margin of optic disc, respectively. All retinal arterioles and venules larger than 25 μm are marked and assessed within zone C.
10.1371/journal.pone.0160704.g002
Examples of retinal venular assessment from two subjects with different diet quality.
Subject in Fig 2a in the upper panel has a unhealthier diet pattern than the subject in Fig 2b. in the lower panel. Comparisons between 2a and 2b are listed below: total mono-unsaturated fat (MUFA) percentage—80.25% vs. 13.45%; total fat intake percentage– 41.8% vs. 36.9%; Health Eating Index for Asian Pregnant Women (HEI-AP)– 27.20 vs. 38.70; central retinal venular equivalent (CRVE)– 180.50 μm vs 145.63 μm.
The gradability of all the mothers’ retinal photographs were up to 98% as reported in previous publications for the same cohort [50,51]. Intra-grader reliability, which was assessed in a ~10% subset (n = 60) with randomly selected retinal photographs from same cohort, ranged from 0.95 to 0.99 for retinal vascular caliber readings.
Assessment of Co-VariatesBlood Pressure Measurement
Left upper arm blood pressure was measured using the automatic Omron sphygmomanometer (Omron HEM 705 LP, Omron Healthcare Inc., US) with an upright seating posture after at least 5 minutes of rest [50,51]. Only two readings were required. Unless the difference was greater than 10 mmHg in systolic blood pressure (SBP) and/or 5 mmHg in diastolic blood pressure (DBP), respectively, a third reading would be applied to calculate the average of the 2 closest readings of SBP and DBP. Mean arterial blood pressure (MABP) was calculated as one third of the SBP plus two thirds of the DBP.
Anthropometric measurement
Height and weight were both measured with standing posture using standard protocol of SECA weighing scale (Vogel and Halke, Germany) [50,51]. Two readings were required with bare feet. Unless the difference was greater than 1.0 cm or 200 grams for height or weight, a third reading would be required for the average height and weight calculation. Body mass index (BMI) was calculated as weight divided by the height squared (kilograms [Kg] per meter squared [m2]).
Other Covariates
Maternal demographic status (maternal education and household income), personal medical history (hypertension and diabetes), smoking, alcohol intake, parity and pre-pregnancy weight were all ascertained using questionnaires administered by trained clinic staff.
Statistical Analysis
Based on the normal distribution of retinal vascular caliber, HEI-AP and total energy intake, all these variables were analyzed as continuous variables. However, the distribution of macronutrients (expressed as % of total energy) and fat types were skewed either to the left or to the right, and were thus log transformed for normalization, before analyses as continuous variables. Comparisons of basic characteristics between included and excluded subjects were done either by student’s t-test or χ2 test. P trend of categories in major variables in relation to retinal vascular caliber was analyzed by factorregression.
Multiple linear regression models were constructed to assess the cross-sectional association between maternal macronutrients and retinal vascular caliber. Stepwise backward methods were selected to choose the most parsimonious and best fitting model. A few models were applied in all analyses. Model 1, unadjusted; Model 2, adjusted for age and ethnicity; Model 3, adjusted for covariates in Model 2 and further adjusted for history of hypertension, history of diabetes, pre-pregnancy overweight or obese status, weight gain at 26–28 weeks and primiparous status.
To evaluate the effects of one macronutrient relative to another in iso-caloric diets, substitution models were further applied in Models 4 to 9 [36,52]. The purpose of applying substitution models was to account for the increment of a macronutrient at the expense of another while keeping the total energy intake constant. For example, when fat and total energy intakes are kept constant, the only macronutrient that can decrease as the percentage of energy from carbohydrate increases is protein. Thus, this model can be considered to be the theoretical substitution of carbohydrates for protein.
Besides covariates in Model 3, model 4 was additionally adjusted for total energy intake and percentage of total fat, to examine the effect of a higher carbohydrate and lower iso-caloric protein diet on retinal vascularisation. In Model 5, co-variates in model 3 were included and then additionally adjusted for total energy intake and percentage of total carbohydrate, to examine the effect of a higher fat, lower protein diet on retinal vascularisation. In Model 6, co-variates in model 3 were included and then additionally adjusted for total energy intake and percentage of total protein, to examine the effect of a higher fat, lower carbohydrate diet on retinal vascularisation.
Similarly, the substitution models were applied for the analyses of different fat types including saturated fat, mono-unsaturated fat (MUFA) and poly-unsaturated fat (PUFA) on retinal vascularisation. Three additional models were applied as below: In Model 7, co-variates in model 3 were included and then additionally adjusted for total energy intake, percentage of total protein, percentage of total carbohydrate and saturated fat percentage, to examine the effect of a higher MUFA, lower PUFA diet or vice versa. Model 8 was adjusted for percentage of MUFA to examine the effects of a higher saturated, lower PUFA diet and vice versa and finally model 9 to examine the effects of a higher saturated, lower MUFA or vice-versa.
A significant p value (2-tailed) was defined as <0.05. All statistical analyses were performed using PASW 19.0 (SPSS Inc, Chicago, U.S.). Effect modification and interaction were tested.
Results
Comparisons of basic characteristics between included and excluded participants are shown in Table 1. Mothers included in this study were similar to those excluded except for a slightly younger age (30.49 years vs. 31.29 years), lower education level (24.27% vs. 39.05% with university degree, being more likely to smoke (13.84% vs. 11.15%) and less likely to drink alcohol (27.85% vs. 37.48%). The mean and standard deviation (SD) of retinal vascular caliber is 120.89 μm (SD = 9.01 μm) in arterioles and 171.33 μm (SD = 12.54 μm) in venules, respectively.
10.1371/journal.pone.0160704.t001
Comparison of baseline characteristics between participants included and excluded in the study.
Characteristics
Participants
p value*
attended
not attended
(n = 614)
(n = 549)
(mean, SD)
(mean, SD)
Age, years
30.49, 5.45
31.29, 4.86
<0.01
Ethnicity, Chinese
49.59
58.39
<0.001
Maternal Education, University
24.27
39.05
<0.001
Hypertension history, Yes %
1.96%
2.55%
0.61
Diabetes history, Yes %
0.98%
2.01%
0.27
weight before pregnancy, Kg
56.93, 11.95
56.89, 11.16
0.90
BMI at 26–28 weeks’ pregnancy, Kg/m2
26.32, 4.49
26.00, 4.86
0.26
Primiparous, Yes %
37.91%
40.23%
0.43
CRAE, μm
120.89, 9.01
120.47, 8.30
0.58
CRVE, μm
171.33, 12.54
169.95, 12.69
0.21
*Statistical analysis was performed either by student’s t-test or χ2 test.
In Table 2, major variables associated with our retinal vascular caliber outcomes were categorized by clinical cut-offs or by 50th percentile. Traditional risk factors such as older age, race with darker skin pigmentation, history of hypertension and diabetes were all correlated with different retinal vascular morphological changes. Interestingly, we also found that pre-pregnancy overweight or obese status, higher weight gain during mid-late pregnancy and being primiparous were correlated with either narrower retinal arteriolar caliber or wider retinal venular caliber.
10.1371/journal.pone.0160704.t002
Basic characteristic in categories in relation to retinal vascular caliber in the GUSTO cohort.
Variables
CRAE, μm
p trend
CRVE, μm
p trend
mean, SD
mean, SD
Demographics
Age
< 35 years (n = 461)
121.24, 8.88
0.17
172.49, 12.60
<0.01
≧ 35 years (n = 153)
120.08, 9.46
168.16, 12.31
Ethnicity
Chinese (n = 317)
120.00, 9.10
<0.01
169.21, 12.39
0.08
Malay (n = 187)
121.59, 8.98
175.00, 12.86
Indian (n = 110)
122.63, 8.66
171.64, 11.71
History of hypertension
Yes (n = 12)
114.72, 11.97
<0.05
166.40, 17.40
0.17
No (n = 602)
121.08, 8.93
171.51, 12.54
History of Type 2 Diabetes
Yes (n = 6)
123.65, 6.73
0.46
171.35, 12.67
0.25
No (n = 608)
120.93, 9.05
171.33, 11.01
Anthropometrics
Pre-pregnancy overweight or obese status
Yes ≧ 25.00 kg/m2 (n = 213)
119.47, 9.00
<0.01
171.23, 12.87
0.97
No < 25.00 kg/m2 (n = 353)
121.75, 8.92
171.27, 12.64
weight gain, mean = 8.45 kg
≤ 50 centile (n = 267)
120.80, 8.79
0.89
169.82, 12.40
<0.05
> 50 centile (n = 282)
120.91, 9.12
172.29, 12.82
Delivery data
Parity
Primiparous (n = 253)
121.86, 8.62
<0.05
173.77, 12.42
<0.001
at least 1 live birth history (n = 357)
120.28, 9.27
169.65, 12.50
P trend was calculated by factor regression.
Abbreviation: CRAE, central retinal arteriolar equivalent; CRVE, central retinal venular equivalent.
Table 3 shows the associations of dietary quality (HEI-AP) and total energy intake with retinal vascular caliber. No associations were observed between total energy intake and retinal vascular caliber. The association between poorer HEI-AP and retinal venular caliber widening was consistently significant across Models 1 to 3. In fully adjusted model, lower HEI-AP score was associated with retinal venular widening (β = 1.70 μm per 20 scores decrease in HEI-AP, p<0.05).
10.1371/journal.pone.0160704.t003
Associations between health eating index (HEI), total energy intakes and retinal vascular caliber among pregnant women during 26–28 weeks’ gestation.
Retinal vessels
HEI-AP
Total energy intake
Each 20 scores ↓
Each 1.0 kcal ↑
CRAE, μm
β, SE
p value
β, SE
p value
Model 1
2.02, 1.14
0.08
2.50, 2.60
0.34
Model 2
1.70, 1.12
0.13
3.66, 2.60
0.16
Model 3
1.72, 1.20
0.15
3.59, 2.76
0.19
CRVE, μm
β, SE
p value
β, SE
p value
Model 1
2.48, 0.80
<0.01
-2.23, 1.86
0.23
Model 2
1.58, 0.80
0.05
-1.03, 1.89
0.59
Model 3
1.70, 0.86
<0.05
-1.24, 1.99
0.53
Abbreviation: SE, standard error, CI, confidence interval; CRAE, central retinal arteriolar equivalent; CRVE, central retinal venular equivalent; HEI-AP, Healthy Eating Index for Asian Pregnant women.
Model 1, unadjusted
Model 2, adjusted for age and ethnicity.
Model 3, Model 2 and additionally adjusted for history of hypertension, history of diabetes, pre-pregnancy overweight or obese status, weight gain at 26–28 weeks and primiparous status.
Table 4 shows the associations between percentage of each macronutrient intake in log scale and retinal vascular caliber. In Model 5, a higher fat and lower protein diet was associated with retinal venular widening (β = 1.84 μm per 0.1 log increase in percentage of total fat intake, p<0.05). Similarly, a higher carbohydrate and lower protein diet had a borderline significant association with retinal venular widening (β = 2.17 μm per 0.1 log increase in percentage of total carbohydrates intake, p = 0.07) (Model 4). No association was seen with a higher fat and lower carbohydrate diet.
10.1371/journal.pone.0160704.t004
Associations between Macronutrients percentage and retinal vascular caliber among pregnant women during 26–28 weeks’ gestation.
Retinal vessels
Total protein %
Total fat %
Total carbohydrates %
Each 0.1 unit ↑ in log
Each 0.1 unit ↑ in log
Each 0.1 unit ↑ in log
CRAE, μm
β, SE
p value
β, SE
p value
β, SE
p value
Model 1
-0.47, 0.34
0.17
0.29, 0.32
0.47
0.17, 0.46
0.72
Model 2
-0.25, 0.34
0.46
0.39, 0.32
0.22
-0.14, 0.46
0.77
Model 3
-0.17, 0.35
0.64
0.25, 0.33
0.45
-0.01, 0.47
0.98
Model 4
-0.17, 0.36
0.63
--
--
0.89, 0.88
0.31
Model 5
-0.16, 0.40
0.70
0.68, 0.63
0.29
--
--
Model 6
--
--
0.15, 0.35
0.66
0.01, 0.55
0.99
CRVE, μm
β, SE
p value
β, SE
p value
β, SE
p value
Model 1
-0.82, 0.47
0.08
0.37, 0.44
0.41
0.43, 0.64
0.50
Model 2
-0.55, 0.47
0.24
0.51, 0.44
0.24
0.01, 0.64
0.88
Model 3
-0.57, 0.49
0.24
0.42, 0.46
0.36
0.11, 0.66
0.87
Model 4
-0.63, 0.49
0.20
--
--
2.17, 1.21
0.07
Model 5
-0.73, 0.56
0.19
1.84, 0.88
<0.05
--
--
Model 6
--
--
0.58, 0.48
0.23
-0.44, 0.76
0.56
Abbreviation: SE, standard error; CRAE, central retinal arteriolar equivalent; CRVE, central retinal venular equivalent.
Model 1: unadjusted
Model 2: adjusted for age and ethnicity.
Model 3: includes Model 2 and additionally adjusted for history of hypertension, history of diabetes, pre-pregnancy overweight or obese status, weight gain at 26–28 weeks and primiparous status.
Model 4: includes Model 3 and additionally adjusted for total energy intake and total fat intake percentage.
Model 5: includes Model 3 and additionally adjusted for total energy intake and total carbohydrate intake percentage.
Model 6: includes Model 3 and additionally adjusted for total energy intake and total protein intake percentage.
Table 5 shows the associations between percentage of each fat type in log scale and retinal vascular caliber. Higher MUFA and lower PUFA or saturated fats diets were consistently associated with retinal venular widening in Model 2, 3 and 7 (β = 1.84 μm per 0.1 log increase in percentage of MUFA intake, p<0.01). An example of changes in retinal venular is shown in Fig 2. Such changes in retinal venular due to different dietary pattern were shown in Fig 2.
10.1371/journal.pone.0160704.t005
Associations between Saturated fat and retinal vascular caliber among pregnant women during 26–28 weeks’ gestation.
Retinal Vessels
Saturated Fat%,
MUFA %,
PUFA %
each 0.1 unit ↑ in log
each 0.1 unit ↑ in log
each 0.1 unit ↑ in log
CRAE, μm
β, SE
p value
β, SE
p value
β, SE
p value
Model 1
-0.01, 0.38
0.99
0.19, 0.43
0.67
-0.08, 0.23
0.72
Model 2
-0.15, 0.39
0.69
0.43, 0.44
0.32
-0.05, 0.23
0.83
Model 3
-0.30, 0.41
0.47
0.72, 0.45
0.11
0.12, 0.25
0.64
Model 7
--
--
0.71, 0.46
0.12
-0.01, 0.38
0.80
Model 8
-0.32, 0.42
0.45
--
--
0.30, 0.27
0.26
Model 9
-0.55, 0.62
0.38
0.94, 0.54
0.08
--
--
CRVE, μm
β, SE
p value
β, SE
p value
β, SE
p value
Model 1
0.41, 0.54
0.44
1.01, 0.60
0.10
-0.48, 0.32
0.14
Model 2
-0.15, 0.53
0.78
1.55, 0.60
0.01
-0.28, 0.31
0.37
Model 3
-0.25, 0.56
0.66
1.82, 0.62
<0.01
-0.29, 0.35
0.41
Model 7
--
--
1.84, 0.63
<0.01
-0.82, 0.53
0.13
Model 8
-0.15, 5.81
0.80
--
--
0.07, 0.38
0.85
Model 9
-1.35,0.87
0.12
1.76, 0.75
<0.05
--
--
Abbreviation: MUFA, mono-unsaturated fat; PUFA, poly-unsaturated fat; SE, standard error; CRAE, central retinal arteriolar equivalent; CRVE, central retinal venular equivalent.
Model 1: unadjusted
Model 2: adjusted for age and ethnicity.
Model 3: incluing Model 2 and additionally adjusted for history of hypertension, history of diabetes, pre-pregnancy overweight or obese status, weight gain at 26–28 weeks and primiparous status.
Model 7: including Model 3 and additionally adjusted for total energy intake, total protein intake percentage, total carbohydrates percentage and total saturated fat intake percentage.
Model 8: including Model 3 and additionally adjusted for total energy intake, total protein intake percentage, total carbohydrates percentage and MUFA percentage.
Model 9: including Model 3 and additionally adjusted for total energy intake, total protein intake percentage, total carbohydrates percentage and PUFA percentage.
No associations were found between the dietary quality index or macronutrient intakes and retinal arteriolar caliber in our cohort. No evidence was found for effect modification or interaction between exposure variables in our study.
Discussion
In our hospital-based, cross-sectional study among multi-ethnicities including Chinese, Malay and Indian pregnant women during their mid-late pregnancy, women with lower dietary quality and diets of higher fat with lower protein tended to have wider retinal venular caliber.
It has been widely accepted that high-fat diet can greatly contribute to long-term development of metabolic disorders [3–5] and cardiovascular disease [6–8]. Substantial evidence from animal experiments [9–11] and human studies [12–15] has suggested that impairment of endothelial and vascular function resulted from either high-fat diet or advanced glycation end products could be the major underlying mechanism. Recent rodent experiments showed that high fat intakes not only increased body weight, but also up-regulated the expression of hypothalamic neuropeptides which were associated with increased visceral and liver adiposity [10,53]. These two types of adiposity are both known to be detrimental to health and associated with disturbed metabolism [54,55]. One of the many hypothesized underlying mechanisms is due to endothelial dysfunction which further leads to small vessel dysfunction and ultimately results in large vessel dysfunction [10]. Thus, high-fat diet related endothelial dysfunction seems to be partially mediated by disturbed production of a wide range of adipose-derived adipokines and inflammatory factors [10,56], and thus subsequently leads to oxidative stress, a possible mediator of vascular dysfunction [10,57].
However, endothelial dysfunction is difficult to assess accurately in vivo, even though substantial evidence has illustrated the important role of endothelial dysfunction as an early event and an underlying factor for metabolic and cardiovascular states including atherosclerosis, hypertension and diabetes [10,57]. The ability to detect early vascular changes in vivo might be a key to reflect endothelial function and real-time inflammatory changes. Retinal microvasculature is the vascular bed that can be viewed non-invasively over time [24]. Morphology of retinal vasculature such as narrowing arterioles, widening in venules, sparser in fractal dimension and more tortuous vessels have been strongly suggested to be associated with endothelial dysfunction by a number of epidemiological studies [25–29]. In recent decade, retinal imaging studies applied to adults and children also found that suboptimal dietary intakes such as high sugar, low fibre and low fish oil intakes were associated with retinal vascular abnormalities as mentioned earlier [30–33]. Unfortunately, such influence of macronutrient intakes is largely lacking in pregnancy women, despite that high-fat diet has been widely established as risk factors for pregnancy complications such as gestational diabetes and pre-eclampsia [16–22].
With the aid of retinal imaging, our study is the first one to look into microvasculature with relation to dietary macronutrient intakes in a large number of Asian pregnant women. We found that a high-fat with low-protein diet was associated with wider retinal venules. As suggested by animal and human experimental studies, high-fat diet associated endothelium-dependent vasodilator dysfunction may down-regulate nitride-oxide (NO) and prostacyclin (PGI2) that are produced by endothelium cells (ECs), which ultimately lead to vascular dysfunction [15,58,59]. Therefore, retinal venular widening might be considered as one of the early signs of vascular morphology indicating the possibility of vascular dysfunction led by sub-optimal dietary pattern. In addition, we found that lower diet quality was associated with wider retinal venules. This is in line with a recent meta-analysis on 15 cohorts, where low scores on diet quality were found to be associated with a significant increment in the risk of type 2 diabetes, cardiovascular disease and all-cause mortality by 28% [60].
Based on the observations in our study, we agree with the reviewer that “low protein” with poor-diet style in terms of either high fat or high carbohydrate intake is associated with adverse retinal microvasculature. While current associations seem to suggest that lower protein diets may play a role in influencing retinal vascular caliber outcomes, the other associations examining higher protein diets at the expense of fat or carbohydrates do not appear to support this. This may in part be due to the small or tight range of log transformed dietary protein intakes percentage in our cohort and this can be further explored in future studies.
Interestingly, in the analysis of each fat component in relation to retinal vascular abnormality, higher MUFA percentage, instead of saturated fat or PUFA, was significantly associated with retinal venular widening. It has been widely suggested in clinical studies that MUFA and PUFA replacing saturated fat in the diet greatly reduced both total and low-density lipoprotein (LDL) cholesterol [61–63], which is beneficial to lower risk of cardiovascular disease development in the future. However, animal studies investigating the influence of dietary fats on atherosclerosis have reported conflicting results. Earlier work on mice and primates showed that a MUFA diet led to more atherosclerosis than both saturated fat and PUFA diets despite a more favourable plasma lipid profile [64–66]. And in our study, our findings between MUFA and retinal vascular abnormality seemed to support such observational result.
The strength of our study includes a large sample size, a novel population (pregnant women) which has not been studied on before, standardized protocols using validated assessments of retinal vasculature, detailed dietary assessments together with detailed information on a range of potential confounders. However, our study also carried a few methodological issues limiting the significance of our study. Firstly, there might be a limited role for selection bias in the 614 participants selected from a total number of 1163 subjects in the whole cohort, even though we did not find any significant differences in major baseline characteristics between these 2 groups. Secondly, recall bias and information bias might occur during only one time dietary data interview during the whole pregnancy. Thirdly, there might be residual confounders such as glycated hemoglobin, lipid profile and C-reactive protein affecting the associations investigated in this study yet not being adjusted for. Due to the lacking of such data, future studies should take these confounders into account.
In this cross-sectional study, we found that pregnant women with a higher fat with lower protein diet and lower dietary quality during mid-late pregnancy tended to have retinal venular caliber widening, a type of retinal vascular morphology indicative of sub-optimal microcirculature and correlated to future metabolic and cardiovascular risks. The relationship between the different types of fats such as MUFA and retinal vascularization needs to be further explored and confirmed.
Supporting Information
Healthy Eating Index for Asian Pregnant Women (HEI-AP) components breakdown.
(TIF)
We thank the GUSTO team and all the participants who have contributed greatly in this study.
The co-authors acknowledge the contribution of the rest of the GUSTO study group which includes Dennis Bier, Arijit Biswas, Cai Shirong, Helen Chan, Jerry Chan, Yiong Huak Chan, Cornelia Chee, Audrey Chia, Chiang Wen Chin, Chng Chai Kiat, Mary Chong, Chong Shang Chee, Chua Mei Chien, Wayne Cutfield, Mary Daniel, Ding Chun Ming, Anne Ferguson-Smith, Eric Andrew Finkelstein, Marielle Fortier, Doris Fok, Anne Goh, Daniel Goh, Joshua J Gooley, Han Wee Meng, Mark Hanson, Mikael Hartman, Michael Heymann, Stephen Hsu Chin-Ying, Hazel Inskip, Jeevesh Kapur, Joanna Holbrook, Lee Bee Wah, B F P Leutscher-Broekman, Lim Sok Bee, Loh Seong Feei, Low Yen Ling, Iliana Magiati, Susan Morton, Krishnamoorthy N, Cheryl Ngo, Pang Wei Wei, Prathiba Agarwal, Qiu Anqi, Quah Boon Long, Jen Richmond, Anne Rifkin-Graboi, Allan Sheppard, Lynette Pei-Chi Shek, Borys Shuter, Leher Singh, So Wing Chee, Walter Stunkel, Su Lin Lin, Tan Kok Hian, Tan Soek Hui, Teoh Oon Hoe, Terry Yoke Yin Tong, Hugo Van Bever, Rob Van Dam, Sudhakar Venkatesh, Helena Marieke Verkooijen, Inez By Wong, P C Wong, George S H Yeo. The GUSTO team leader: A/Prof. Yap-Seng Chong, Acting Executive Director, Singapore Institute for Clinical Sciences, Brenner Centre for Molecular Medicine, 30 Medical Drive, S117609. (DID): +65 6407 0372; (Fax): +65 6776 6840. Email: yap_seng_chong@nuhs.edu.sg.
ReferencesBialostoskyK, WrightJD, Kennedy-StephensonJ, McDowellM, JohnsonCL (2002) Dietary intake of macronutrients, micronutrients, and other dietary constituents: United States 1988–94. 11: 1–158.Rolland-CacheraMF, DeheegerM, AkroutM, BellisleF (1995) Influence of macronutrients on adiposity development: a follow up study of nutrition and growth from 10 months to 8 years of age. 19: 573–578. 7489029HuFB, van DamRM, LiuS (2001) Diet and risk of Type II diabetes: the role of types of fat and carbohydrate. 44: 805–817. 11508264NettletonJA, SteffenLM, NiH, LiuK, JacobsDRJr. (2008) Dietary patterns and risk of incident type 2 diabetes in the Multi-Ethnic Study of Atherosclerosis (MESA). 31: 1777–1782. doi: 10.2337/dc08-076018544792van DamRM, WillettWC, RimmEB, StampferMJ, HuFB (2002) Dietary fat and meat intake in relation to risk of type 2 diabetes in men. 25: 417–424. 11874924HaysJH, DiSabatinoA, GormanRT, VincentS, StillabowerME (2003) Effect of a high saturated fat and no-starch diet on serum lipid subfractions in patients with documented atherosclerotic cardiovascular disease. 78: 1331–1336. 14601690HelajarviH, PahkalaK, HeinonenOJ, JuonalaM, OikonenM, et al. (2015) Television viewing and fatty liver in early midlife. The Cardiovascular Risk in Young Finns Study. : 1–8.TektonidisTG, AkessonA, GiganteB, WolkA, LarssonSC (2015) A Mediterranean diet and risk of myocardial infarction, heart failure and stroke: A population-based cohort study. 243: 93–98. doi: 10.1016/j.atherosclerosis.2015.08.03926363438BonettiPO, LermanLO, LermanA (2003) Endothelial dysfunction: a marker of atherosclerotic risk. 23: 168–175. 12588755HeinonenI, RinneP, RuohonenST, RuohonenS, AhotupaM, et al. (2014) The effects of equal caloric high fat and western diet on metabolic syndrome, oxidative stress and vascular endothelial function in mice. 211: 515–527.SauderKA, ProctorDN, ChowM, TroyLM, WangN, et al. (2015) Endothelial function, arterial stiffness and adherence to the 2010 Dietary Guidelines for Americans: a cross-sectional analysis. 113: 1773–1781. doi: 10.1017/S000711451500085925885520TsaiWC, LiYH, LinCC, ChaoTH, ChenJH (2004) Effects of oxidative stress on endothelial function after a high-fat meal. 106: 315–319.NegreanM, StirbanA, StratmannB, GawlowskiT, HorstmannT, et al. (2007) Effects of low- and high-advanced glycation endproduct meals on macro- and microvascular endothelial function and oxidative stress in patients with type 2 diabetes mellitus. 85: 1236–1243. 17490958DerosaG, FerrariI, D'AngeloA, SalvadeoSA, FogariE, et al. (2009) Oral fat load effects on inflammation and endothelial stress markers in healthy subjects. 24: 204–210. doi: 10.1007/s00380-008-1109-y19466522DowCA, StaufferBL, GreinerJJ, DeSouzaCA (2015) Influence of habitual high dietary fat intake on endothelium-dependent vasodilation. 40: 711–715. doi: 10.1139/apnm-2015-000626058441SaldanaTM, Siega-RizAM, AdairLS (2004) Effect of macronutrient intake on the development of glucose intolerance during pregnancy. 79: 479–486. 14985225LeySH, HanleyAJ, RetnakaranR, SermerM, ZinmanB, et al. (2011) Effect of macronutrient intake during the second trimester on glucose metabolism later in pregnancy. 94: 1232–1240. doi: 10.3945/ajcn.111.01886121955650BoS, MenatoG, LezoA, SignorileA, BardelliC, et al. (2001) Dietary fat and gestational hyperglycaemia. 44: 972–978. 11484073RadeskyJS, OkenE, Rifas-ShimanSL, KleinmanKP, Rich-EdwardsJW, et al. (2008) Diet during early pregnancy and development of gestational diabetes. 22: 47–59. doi: 10.1111/j.1365-3016.2007.00899.x18173784OlafsdottirAS, SkuladottirGV, ThorsdottirI, HaukssonA, ThorgeirsdottirH, et al. (2006) Relationship between high consumption of marine fatty acids in early pregnancy and hypertensive disorders in pregnancy. 113: 301–309. 16487202WilliamsMA, HavelPJ, SchwartzMW, LeisenringWM, KingIB, et al. (1999) Pre-eclampsia disrupts the normal relationship between serum leptin concentrations and adiposity in pregnant women. 13: 190–204. 10214609KhoiganiMG, PaknahadZ, MardanianF (2012) The relationship between nutrients intake and preeclampsia in pregnant women. : S210–S217.RobertsJM, BalkJL, BodnarLM, BelizanJM, BergelE, et al. (2003) Nutrient involvement in preeclampsia. 133: 1684S–1692S. 12730485CheungCY, IkramMK, SabanayagamC, WongTY (2012) Retinal microvasculature as a model to study the manifestations of hypertension. 60: 1094–1103. doi: 10.1161/HYPERTENSIONAHA.111.18914223045470WongTY, IslamFM, KleinR, KleinBE, CotchMF, et al. (2006) Retinal vascular caliber, cardiovascular risk factors, and inflammation: the multi-ethnic study of atherosclerosis (MESA). 47: 2341–2350. 16723443Van HeckeMV, DekkerJM, NijpelsG, TeerlinkT, JakobsC, et al. (2008) Homocysteine, S-adenosylmethionine and S-adenosylhomocysteine are associated with retinal microvascular abnormalities: the Hoorn Study. 114: 479–487.LiewG, SharrettAR, WangJJ, KleinR, KleinBE, et al. (2008) Relative importance of systemic determinants of retinal arteriolar and venular caliber: the atherosclerosis risk in communities study. 126: 1404–1410. doi: 10.1001/archopht.126.10.140418852419KleinR, KleinBE, KnudtsonMD, WongTY, TsaiMY (2006) Are inflammatory factors related to retinal vessel caliber? The Beaver Dam Eye Study. 124: 87–94. 16401789GopinathB, WangJJ, FloodVM, BurlutskyG, WongTY, et al. (2009) The associations between blood levels of homocysteine, folate, vitamin B12, and retinal vascular caliber. 148: 902–909. doi: 10.1016/j.ajo.2009.07.01819796756GopinathB, FloodVM, BurlutskyG, LouieJC, BaurLA, et al. (2014) Dairy food consumption, blood pressure and retinal microcirculation in adolescents. 24: 1221–1227. doi: 10.1016/j.numecd.2014.05.01424996501GopinathB, FloodVM, WangJJ, SmithW, RochtchinaE, et al. (2012) Carbohydrate nutrition is associated with changes in the retinal vascular structure and branching pattern in children. 95: 1215–1222. doi: 10.3945/ajcn.111.03164122456656KaushikS, WangJJ, FloodV, LiewG, SmithW, et al. (2008) Frequency of fish consumption, retinal microvascular signs and vascular mortality. 15: 27–36. 17907016KaushikS, WangJJ, WongTY, FloodV, BarclayA, et al. (2009) Glycemic index, retinal vascular caliber, and stroke mortality. 40: 206–212. doi: 10.1161/STROKEAHA.108.51381218948616SohSE, TintMT, GluckmanPD, GodfreyKM, Rifkin-GraboiA, et al. (2014) Cohort profile: Growing Up in Singapore Towards healthy Outcomes (GUSTO) birth cohort study. 43: 1401–1409. doi: 10.1093/ije/dyt12523912809ChenLW, LowYL, FokD, HanWM, ChongYS, et al. (2014) Dietary changes during pregnancy and the postpartum period in Singaporean Chinese, Malay and Indian women: the GUSTO birth cohort study. 17: 1930–1938. doi: 10.1017/S136898001300173023806144ChongMF, ChiaAR, ColegaM, TintMT, ArisIM, et al. (2015) Maternal Protein Intake during Pregnancy Is Not Associated with Offspring Birth Weight in a Multiethnic Asian Population. 145: 1303–1310. doi: 10.3945/jn.114.20594825948786YuYM, ChanYH, CalderPC, HardjojoA, SohSE, et al. (2015) Maternal PUFA status and offspring allergic diseases up to the age of 18 months. 113: 975–983. doi: 10.1017/S000711451500001X25746049ConwayJM, IngwersenLA, VinyardBT, MoshfeghAJ (2003) Effectiveness of the US Department of Agriculture 5-step multiple-pass method in assessing food intake in obese and nonobese women. 77: 1171–1178. 12716668CrawfordPB, ObarzanekE, MorrisonJ, SabryZI (1994) Comparative advantage of 3-day food records over 24-hour recall and 5-day food frequency validated by observation of 9- and 10-year-old girls. 94: 626–630. 8195550De KeyzerW, HuybrechtsI, De VriendtV, VandevijvereS, SlimaniN, et al. (2011) Repeated 24-hour recalls versus dietary records for estimating nutrient intakes in a national food consumption survey. 55.MaY, OlendzkiBC, PagotoSL, HurleyTG, MagnerRP, et al. (2009) Number of 24-hour diet recalls needed to estimate energy intake. 19: 553–559. doi: 10.1016/j.annepidem.2009.04.01019576535http://www.hpb.gov.sg/HOPPortal/. HPBSISHladpicAf.WirtA, CollinsCE (2009) Diet quality—what is it and does it matter?12: 2473–2492. doi: 10.1017/S136898000900531X19335941HanChad YixianCM, QuahElaine, GodfreyKeith, KwekKenneth, SawSeang-Mei, GluckmanPeter, ChongYap-Seng, ChanYiong Huad, Foong Fong ChongMary. (2015) A healthy eating index to measure diet quality in pregnant women in Singapore: a cross-sectional study. 1.GuentherPM, CasavaleKO, ReedyJ, KirkpatrickSI, HizaHA, et al. (2013) Update of the Healthy Eating Index: HEI-2010. 113: 569–580. doi: 10.1016/j.jand.2012.12.01623415502GuentherPM, ReedyJ, Krebs-SmithSM (2008) Development of the Healthy Eating Index-2005. 108: 1896–1901. doi: 10.1016/j.jada.2008.08.01618954580KennedyET, OhlsJ, CarlsonS, FlemingK (1995) The Healthy Eating Index: design and applications. 95: 1103–1108. 7560680Rifas-ShimanSL, Rich-EdwardsJW, KleinmanKP, OkenE, GillmanMW (2009) Dietary quality during pregnancy varies by maternal characteristics in Project Viva: a US cohort. 109: 1004–1011. doi: 10.1016/j.jada.2009.03.00119465182Pregnancy and Diet. Health Promotion Board Singapore; 2014.LiLJ, CheungCY, IkramMK, GluckmanP, MeaneyMJ, et al. (2012) Blood pressure and retinal microvascular characteristics during pregnancy: Growing Up in Singapore Towards Healthy Outcomes (GUSTO) Study. 60: 223–230. doi: 10.1161/HYPERTENSIONAHA.112.19540422615113LiLJ, IkramMK, CheungCY, LeeYS, LeeLJ, et al. (2012) Effect of maternal body mass index on the retinal microvasculature in pregnancy. 120: 627–635. 22914473MaslovaE, RytterD, BechBH, HenriksenTB, RasmussenMA, et al. (2014) Maternal protein intake during pregnancy and offspring overweight 20 y later. 100: 1139–1148. doi: 10.3945/ajcn.113.08222225099541LiangC, DeCourcyK, PraterMR (2010) High-saturated-fat diet induces gestational diabetes and placental vasculopathy in C57BL/6 mice. 59: 943–950. doi: 10.1016/j.metabol.2009.10.01520022072KotronenA, WesterbackaJ, BergholmR, PietilainenKH, Yki-JarvinenH (2007) Liver fat in the metabolic syndrome. 92: 3490–3497. 17595248SmithBW, AdamsLA (2011) Nonalcoholic fatty liver disease and diabetes mellitus: pathogenesis and treatment. 7: 456–465. doi: 10.1038/nrendo.2011.7221556019AldhahiW, HamdyO (2003) Adipokines, inflammation, and the endothelium in diabetes. 3: 293–298. 12866991MusaMG, TorrensC, CloughGF (2014) The microvasculature: a target for nutritional programming and later risk of cardio-metabolic disease. 210: 31–45.KaiserN, LeibowitzG (2009) Failure of beta-cell adaptation in type 2 diabetes: Lessons from animal models. 14: 1099–1115.YamagataK, TagamiM, YamoriY (2015) Dietary polyphenols regulate endothelial function and prevent cardiovascular disease. 31: 28–37. doi: 10.1016/j.nut.2014.04.01125466651SchwingshacklL, HoffmannG (2015) Diet quality as assessed by the Healthy Eating Index, the Alternate Healthy Eating Index, the Dietary Approaches to Stop Hypertension score, and health outcomes: a systematic review and meta-analysis of cohort studies. 115: 780–800e785. doi: 10.1016/j.jand.2014.12.00925680825KratzM, CullenP, KannenbergF, KassnerA, FobkerM, et al. (2002) Effects of dietary fatty acids on the composition and oxidizability of low-density lipoprotein. 56: 72–81. 11840183MontoyaMT, PorresA, SerranoS, FruchartJC, MataP, et al. (2002) Fatty acid saturation of the diet and plasma lipid concentrations, lipoprotein particle concentrations, and cholesterol efflux capacity. 75: 484–491. 11864853RajaramS, BurkeK, ConnellB, MyintT, SabateJ (2001) A monounsaturated fatty acid-rich pecan-enriched diet favorably alters the serum lipid profile of healthy men and women. 131: 2275–2279. 11533266MerkelM, Velez-CarrascoW, HudginsLC, BreslowJL (2001) Compared with saturated fatty acids, dietary monounsaturated fatty acids and carbohydrates increase atherosclerosis and VLDL cholesterol levels in LDL receptor-deficient, but not apolipoprotein E-deficient, mice. 98: 13294–13299. 11606787RudelLL, KelleyK, SawyerJK, ShahR, WilsonMD (1998) Dietary monounsaturated fatty acids promote aortic atherosclerosis in LDL receptor-null, human ApoB100-overexpressing transgenic mice. 18: 1818–1827. 9812923RudelLL, ParksJS, SawyerJK (1995) Compared with dietary monounsaturated and saturated fat, polyunsaturated fat protects African green monkeys from coronary artery atherosclerosis. 15: 2101–2110. 7489230