Amir Kaviani

Fetal tissue engineering from amniotic fluid

BACKGROUND We have recently shown, in an animal model, that amniotic fluid can be a source of cells for fetal tissue engineering. This study was aimed at determining whether fetal tissue constructs could also be engineered from cells normally found in human amniotic fluid. STUDY DESIGN Cells obtained from the amniotic fluid of pregnant women at 15 to 19 weeks of gestation (n=6) were cultured in Dulbeccos Modified Eagles medium (Sigma Chemical, St Louis, MO) containing 20% fetal bovine serum and 5 ng/mL basic fibroblast growth factor in a 95% humidified, 5% CO(2) chamber at 37 degrees C. A subpopulation of morphologically distinct cells was then mechanically isolated from the rest and selectively expanded. The lineage of this subpopulation of amniocytes was determined by immunofluorescent staining with antibodies against standard intermediate filaments and surface antigens. Cell proliferation rates were determined by oxidation assay. After cell expansion, colonies of amniocytes were statically and dynamically seeded onto both unwoven, 1-mm-thick polyglycolic acid polymer scaffold and acellular human dermis for 72 hours. The resulting constructs were analyzed by scanning electron microscopy. RESULTS Amniocytes stained positively for smooth muscle actin, vimentin, cytokeratin 18, and fibroblast surface protein, and negatively for desmin, cluster of differentiation 31, and von Willebrands factor (Dako, Carpenteria, CA). These findings are consistent with a mesenchymal, fibroblast-myofibroblast cell lineage. Mesenchymal amniocytes could be rapidly expanded in culture, based on results of the proliferation assay. Scanning electron microscopy of amniocyte constructs revealed dense, confluent layers of cells surrounding the polymer matrices and firm cell adhesion to both PGA and Alloderm (Lifecell Corp, Branchburg, NJ) scaffolds. No evidence of cell death was observed. CONCLUSIONS Subpopulations of fetal mesenchymal cells can be consistently isolated from human amniotic fluid and rapidly expanded in vitro. Human mesenchymal amniocytes attach firmly to both polyglycolic acid polymer and acellular human dermis. The amniotic fluid can be a valuable and practical cell source for fetal tissue engineering.

Trophic enteral nutrition increases hepatic glutathione and protects against peroxidative damage after exposure to endotoxin.

BACKGROUND During total parenteral nutrition (TPN), hepatic concentration of the important intracellular antioxidant glutathione (GSH) is decreased. This study sought to determine whether enteral trophic (small quantity) feeding of GSH precursors would increase hepatic GSH levels during TPN and result in decreased peroxidative injury after endotoxin exposure. METHODS Sprague-Dawley rats received full TPN for 7 days with postpyloric infusions of either (1) amino acid GSH precursors (cysteine, 60 mg/d; glycine, 86 mg/d; glutamate, 31 mg/d; F1); (2) iso-nitrogenous alanine (132 mg/d; F2); or (3) normal saline (SA). Hepatic GSH concentration was measured by gas chromatography/mass spectrometry. In a parallel study, animals were given TPN and either F1 or SA for 7 days, and endotoxin was administered intravenously before death. Hepatic lipid peroxidation and histology were assessed. RESULTS Hepatic GSH concentration measured 11.7 +/- 0.6 micromol/g in F1. This was significantly higher (P <.001) than in F2 (7.0 +/- 0.8 micromol/g) or SA (5.0 +/- 0.4 micromol/g). F2 and SA were not significantly different. Hepatic malondialdehyde concentration after exposure to endotoxin was significantly higher in SA (10.36 micromol/g +/- 0.65) than in F1 (7.38 micromol/g +/- 0.77; P <.01). All SA animals had histologic evidence of hepatic necrosis, whereas none of the F1 group showed these changes. CONCLUSIONS Targeted trophic feeding of GSH amino acid precursors during parenteral nutrition markedly increased hepatic GSH concentration. This was associated with decreased lipid peroxidation and enhanced hepatocellular protection after endotoxin challenge. Thus, targeted trophic feedings may aid in the prevention of TPN-related liver disease.