Background & Aims: Racial/ethnic disparities in liver transplantation (LT) are wellrecognized. Although Hispanics represent the largest and youngest minority group in the United States, limited data exist on long-term outcomes. We aimed to investigate long-term post-liver transplant outcomes in Hispanic patients and identify potential disparities compared to a baseline demographic of non-Hispanic white patients. Methods: We performed a retrospective cohort study of first-time liver transplant recipients using the United Network for Organ Sharing database from 2002 to 2013, with follow-up through 2018. The primary outcomes of interest were overall patient and graft survival after LT. Results: 45 767 patients underwent LT (85.0% non-Hispanic white, 15.0% Hispanic).Hispanics had lower socioeconomic status, higher prevalence of pretransplant comorbidities and more severe liver disease compared to non-Hispanic whites. Hispanics had similar patient (76.6% vs 75.6%; P = .12) and graft (71.7% vs 70.8%; P = .28) survival at 5 years and significantly better patient (62.9% vs 59.7%; P < .001) and graft (58.6% vs 55.6%; P = .002) survival at 10 years. In multivariable analysis, Hispanics had lower associated all-cause mortality (HR 0.86, 95% CI, 0.82-0.91; P < .001) and graft failure (HR 0.89, 95% CI, 0.85-0.93; P < .001) compared to non-Hispanic whites.In etiology-specific subanalysis, Hispanics transplanted for ALD, NASH and HCV had lower all-cause mortality compared to non-Hispanic whites.
Background Long-chain polyunsaturated fatty acids (LCPUFAs) play a critical role in neonatal health. We hypothesized that LCPUFAs play an essential role in priming postnatal gut development. We studied the effect of LCPUFAs on postnatal gut development using fat-1 transgenic mice, which are capable of converting n-6 to n-3 LCPUFAs, and wild-type (WT) C57BL/6 mice. Results Fat-1 mice, relative to WT mice, showed increased n-3 LCPUFAs levels (α-linolenic acid, docosahexaenoic acid and eicosapentaenoic acid, p <0.05) and decreased arachidonic acid levels ( p <0.05) in the ileum. Pre-weaning fat-1 mice, compared to WT, showed >50% reduced muc2, Tff3, TLR9 and Camp expression ( p <0.05), markers of the innate immune response. There was a >2-fold increased expression of Fzd5 and EphB2 , markers of cell differentiation ( p <0.05), and Fabp2 and 6 , regulators of fatty acid transport and metabolism ( p <0.05). Despite reduced expression of tight junction genes, intestinal permeability in fat-1 was comparable to WT mice. Conclusions Our data support the hypothesis that fatty acid profiles early in development modulate intestinal gene expression in formative domains such as cell differentiation, tight junctions, other innate host defenses, and lipid metabolism.
Prematurity and enteral feedings are major risk factors for intestinal injury leading to necrotizing enterocolitis (NEC). An immature digestive system can lead to maldigestion of macronutrients and increased vulnerability to intestinal injury. The aim of this study was to test in neonatal mice the effect of maltodextrin, a complex carbohydrate, on the risk of intestinal injury. The goal was to develop a robust and highly reproducible murine model of intestinal injury that allows insight into the pathogenesis and therapeutic interventions of nutrient-driven intestinal injury. Five- to 6-day-old C57BL/6 mice were assigned to the following groups: dam fed (D); D+hypoxia+Klebsiella pneumoniae; maltodextrin-dominant human infant formula (M) only; M+hypoxia; and M+hypoxia+K. pneumoniae. The mice in all M groups were gavage fed five times a day for 4 days. Mice were exposed to hypoxia twice a day for 10 min prior to the first and last feedings, and K. pneumoniae was added to feedings as per group assignment. Mice in all M groups demonstrated reduced body weight, increased small intestinal dilatation and increased intestinal injury scores. Maltodextrin-dominant infant formula with hypoxia led to intestinal injury in neonatal mice accompanied by loss of villi, increased MUC2 production, altered expression of tight junction proteins, enhanced intestinal permeability, increased cell death and higher levels of intestinal inflammatory mediators. This robust and highly reproducible model allows for further interrogation of the effects of nutrients on pathogenic factors leading to intestinal injury and NEC in preterm infants.This article has an associated First Person interview with the first author of the paper.
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