Body fat differences by self-reported race/ethnicity in healthy term newborns.

BACKGROUND: Ethnic differences in total body fat (fat mass [FM]) have been reported in adults and children, but the timing of when these differences manifest and whether they are present at birth are unknown. OBJECTIVES: This study aimed to assess whether ethnic differences in body fat are present at birth in healthy infants born at term, where body fat is measured using air displacement plethysmography and fat distribution by skin-fold thickness. METHODS: Data were from a multiracial cross-sectional convenience sample of 332 term infants from four racial or ethnic groups based on maternal self-report (A, Asian; AA, non-Hispanic Black [African-American]; C, non-Hispanic White; and H, Hispanic). The main outcome measure was infant body fat at 1-3 days after birth, with age, birth weight, gestational age and maternal pre-pregnancy weight as covariates. RESULTS: Significant effects for race (P = 0.0011), sex (P = 0.0051) and a race by sex interaction (P = 0.0236) were found. C females had higher FM than C males (P = 0.0001), and AA females had higher FM than AA males (P = 0.0205). C males had less FM than A males (P = 0.0353) and H males (P = 0.0001). CONCLUSION: Race/ethnic and sex differences in FM are present in healthy term newborns. Although the implications of these differences are unclear, studies beginning in utero and birth set the stage for a life course approach to understanding disease later in life.

Maternal obesity influences the relationship between location of neonate fat mass and total fat mass.

BACKGROUND: It is suggested that maternal obesity perpetuates offspring obesity to future generations. OBJECTIVE: To determine whether location of neonate fat mass (FM: central vs. peripheral) is related to total neonate FM and whether maternal obesity influences this relationship. METHODS: Neonate body composition and skin-fold thicknesses were assessed in healthy neonates (n = 371; 1-3 days old). Linear regression models examined the relationship between total FM and location of FM (central vs. peripheral). Location of FM was calculated by skin-folds: peripheral was the sum of (biceps and triceps)/2 and central was represented by the subscapular skin-fold. RESULTS: A significant interaction was found for location of FM and maternal obesity. Holding all predictors constant, in offspring born to non-obese mothers, a 0.5 mm increase in central FM predicted a 15 g greater total FM, whereas a 0.5 mm increase in peripheral FM predicted a 66 g greater total FM. However, in offspring born to obese mothers, a 0.5 mm increase in central FM predicted a 56 g total FM, whereas a 0.5 mm increase in peripheral FM predicted a 14 g greater total FM. CONCLUSIONS: The relationship between total FM and location of FM is influenced by maternal obesity.

Dilinoleoylphosphatidylcholine protects human low density lipoproteins against oxidation.

LDL oxidation may promote atherosclerosis. We found that polyenyphosphatidylcholine (PPC), a mixture of polyunsaturated phospholipids extracted from soybeans, has antioxidant effects in in vivo models of oxidative stress. To assess whether components of PPC affect the in vitro oxidizability of LDL, plasma from 15 healthy volunteers was incubated with 10 microM of either dilinoleoyl-, palmitoyl-linoleoyl-, linoleoyl-palmitoyl- or distearoyl-phosphatidylcholine as well as 10 microM and 1 mM alpha-tocopherol. LDL oxidation was initiated with 5 microM Cu(2+) sulfate and monitored by conjugated diene production, or with 2, 2'-azobis (2-amidinopropane) dihydrochloride, a free radical generator, and monitored by O(2) consumption. After addition of Cu(2+), the lag phase (indicative of resistance of LDL to oxidation) was longer (140% of controls; P<0.001) for LDL incubated with dilinoleoyl-, but not with the other phosphatidylcholine species. This effect was similar to that of 1 mM alpha-tocopherol (135%). After addition of 2,2'-azobis (2-amidinopropane) dihydrochloride, the inhibition time (also reflecting the antioxidant content of LDL) was prolonged (P<0.001) for alpha-tocopherol (206%) and dilinoleoyl-(188%), but not for distearoyl-phosphatidyl-choline. Thus, dilinoleoyl-phosphatidylcholine (the main component of PPC) protects against LDL oxidation, a possible mechanism for its reported anti-atherosclerosis effects.

Oxidation of LDL in baboons is increased by alcohol and attenuated by polyenylphosphatidylcholine.

Alcohol taken in moderation may prevent atherosclerosis, whereas heavy drinking has the opposite effect, in part by promoting oxidation of low density lipoproteins (LDL), a pathogenetic factor in atherogenesis. We assess here: 1 ) whether similar alterations can be reproduced in baboons fed 50% of energy as ethanol (the average intake of alcoholics) for 7- 8 years, and 2 ) whether such alterations are affected by supplementation with polyenylphosphatidylcholine (PPC), a mixture of polyunsaturated phosphatidylcholines, shown to prevent alcoholic fatty liver, fibrosis, and cirrhosis. Ten animals were given the ethanol-containing diet and ten were pair-fed isocaloric control diets. In half of the pairs, the diets were supplemented with 2.8 g of polyenylphosphatidylcholine/1000 kcal. Alcohol feeding increased LDL-lipoperoxides and made LDL-proteins more negatively charged, changes that were attenuated or prevented by PPC. The oxidizability of LDL was determined in vitro by the formation of conjugated dienes after oxidation with copper. Alcohol shortened the lag time (which measures LDL antioxidant capacity); this effect was normalized by PPC supplementation. By contrast, PPC produced no changes in the controls. Thus polyenylphosphatidylcholine, by markedly attenuating the ethanol-induced increase in LDL oxidation, opposes one of the effects whereby alcohol promotes atherosclerosis.

Polyenylphosphatidylcholine attenuates alcohol-induced fatty liver and hyperlipemia in rats.

Chronic administration of a soybean-derived polyenylphosphatidylcholine (PPC) extract prevents the development of cirrhosis in alcohol-fed baboons. To assess whether this phospholipid also affects earlier changes induced by alcohol consumption (such as fatty liver and hyperlipemia), 28 male rat littermates were pair-fed liquid diets containing 36% of energy either as ethanol or as additional carbohydrate for 21 d, and killed 90 min after intragastric administration of the corresponding diets. Half of the rats were given PPC (3 g/l), whereas the other half received the same amount of linoleate (as safflower oil) and choline (as bitartrate salt). PPC did not affect diet or alcohol consumption [15.4 +/- 0.5 G/(kg.d)], but the ethanol-induced hepatomegaly and the hepatic accumulation of lipids (principally triglycerides and cholesterol esters) and proteins were about half those in rats not given PPC. The ethanol-induced postprandial hyperlipemia was lower with PPC than without, despite an enhanced fat absorption and no difference in the level of plasma free fatty acids. The attenuation of fatty liver and hyperlipemia was associated with correction of the ethanol-induced inhibition of mitochondrial oxidation of palmitoyl-1-carnitine and the depression of cytochrome oxidase activity, as well as the increases in activity of serum glutamate dehydrogenase and aminotransferases. Thus, PPC attenuates early manifestations of alcohol toxicity, at least in part, by improving mitochondrial injury. These beneficial effects of PPC at the initial stages of alcoholic liver injury may prevent or delay the progression to more advanced forms of alcoholic liver disease.

Polyenylphosphatidylcholine decreases alcoholic hyperlipemia without affecting the alcohol-induced rise of HDL-cholesterol.

In ethanol-fed rats, supplementation of the diet with soybean polyenylphosphatidylcholine (3 g/liter for 21 days) markedly decreased postprandial VLDL-triglycerides and both VLDL- and LDL-cholesterol levels, whereas it maintained high levels of HDL-cholesterol, compared to an equivalent intake of choline and polyunsaturated fatty acids. By contrast, there were no changes in the serum lipoproteins of the pair-fed controls. The prevention of alcoholic hypertriglyceridemia was associated with marked attenuation of the alcoholic fatty liver and it occurred despite a slight increase in fat absorption. Thus, the administration of polyenylphosphatidylcholine not only attenuates the hepatotoxicity of ethanol, but also increases the HDL/LDL cholesterol ratio, which may be beneficial for the prevention of atherosclerosis and coronary heart disease.

Neutral sterol excretions in rats fed skim milk and skim milk yogurt diets.

Acceleration of cholesterol catabolism (through feces) has been proposed as one of the mechanisms for the hypocholesterolemic effect of dairy products. This study examined the effects of feeding two milk products (skim milk and skim milk yogurt) on fecal neutral sterol excretions in rats. Six groups of nine rats each were fed iso-caloric Chow-based diets containing water, 45% skim milk (SM), or 45% skim milk yogurt (SMY), without or with cholesterol. The results indicate that both SM and SMY increased the excretion of total neutral sterols under hyperlipemic conditions. The SMY diet (with cholesterol) also increased the excretion of coprostanol, a bacterial metabolite.

Effects of skim milk, skim milk yogurt, orotic acid, and uric acid on lipid metabolism in rats.

The effects of feeding two milk products (skim milk and skim milk yogurt) and two proposed hypocholesterolemic factors (orotic acid and uric acid) on serum cholesterol (HDL, LDL, total, HDL/Total and HDL/LDL), liver lipids (total liver lipids and liver cholesterol), and aortal cholesterol were studied. Ten groups, of nine rats each, were fed isocaloric Chow-based diets containing water, 45% skim milk (SM), 45% skim milk yogurt (SMY), and 0.0025% orotic acid (OA) or 0.001% uric acid (UA), without or with cholesterol. The SM diet (with cholesterol) resulted not only in lower total cholesterol (P < 0.10), LDL cholesterol (P < 0.05), aortal cholesterol (P < 0.01), and liver cholesterol (P < 0.10), but also in increased HDL (P < 0.05) and HDL/LDL (P < 0.10) cholesterol ratio. The SMY diet, on the other hand, resulted in lowered total serum cholesterol (P < 0.05) and aortal cholesterol (P < 0.01) and in higher LDL (P < 0.05) cholesterol. The hypocholesterolemic effects were more marked for SM than for SMY. Addition of OA and UA to diets increased serum cholesterol, LDL cholesterol, and total liver lipids; the OA diet also increased liver cholesterol. Neither OA nor UA alone was the factor responsible for the hypocholesterolemic effects seen with SM and SMY feeding.