Reference intervals for plasma sulfate and urinary sulfate excretion in pregnancy.

BACKGROUND: Sulfate is important for fetal growth and development. During pregnancy, the fetus relies on sulfate from the maternal circulation. We report reference intervals for maternal plasma sulfate levels and fractional excretion index (FEI) for sulfate in pregnancy, as well as sulfate levels in cord blood from term pregnancies. METHODS: Plasma and urine were collected from 103 pregnant women of 10-20 weeks gestation and 106 pregnant women of 30-37 weeks gestation. Venous cord plasma was collected from 80 healthy term babies. Sulfate levels were measured by ion chromatography. Plasma and urinary creatinine levels were used to calculate FEI sulfate in pregnant women. Analyses provide reference intervals, and explored the relationship between maternal sulfate data with several prenatal factors. RESULTS: Median maternal plasma sulfate levels were 452 µmol/L and 502 µmol/L at 10-20 and 30-37 weeks gestation, respectively, and inversely correlated with FEI sulfate median values of 0.15 and 0.11. Overall reference intervals were 305-710 and 335-701 µmol/L (2.5th; 97.5th percentile; for 10-20 and 30-37 weeks gestation, respectively) for maternal plasma sulfate, and 0.06-0.31 and 0.05-0.28 for maternal FEI sulfate. Term venous cord plasma sulfate median levels were significantly (p = 0.038) higher in female babies (375 µmol/L) when compared to male babies (342 µmol/L), with an overall reference interval of 175-603 µmol/L. CONCLUSIONS: We provide the first reference intervals for maternal plasma sulfate levels and FEI sulfate, as well as cord plasma sulfate levels. These findings provide reference data for further studies of sulfate levels in both mother and child.

Pyridoxine supply in human development.

Vitamin B(6) has an important role in the function of the human nervous system. Experimental data are not generally available on the role in human development, but significant conclusions may be made from studies of the effect of disorders of B(6) vitamer metabolism. Vitamin B(6) comprises seven compounds - pyridoxal, pyridoxine, pyridoxamine and their respective 5' phosphates. The common active form in human tissue is the 5'-phosphate form of pyridoxal (PLP) most of which is found in muscle bound to phosphorylase. Like many vitamins, B(6) can function both as a co-enzyme and as a chaperone. Pyridoxal-5'-phosphate is the metabolically active form and is involved in 100 enzymatic reactions including carbohydrate, amino acid, and fatty acid metabolism. There is evidence that in some situations B(6) vitamers can function as antioxidants. The fetus is dependent on the placenta for supply of vitamin B(6) and the demand correlates with amino acid metabolism. Few reports are available on the role of B(6) in embryogenesis. Studies of human disorders where B(6) metabolism is blocked show a major role in neurotransmitter function with secondary cerebral and cerebellar hypoplasia. Pyridoxine potentiates vitamin A teratogenicity and an excess leads to peripheral nerve cell degeneration. The key role of vitamin B(6) in the developing human is in metabolism, especially of the neurotransmitters.