Comparison of Patients' and Doctors' Reports on Health-related Quality of Life in Celiac Disease.

OBJECTIVE: To investigate whether implementation of a celiac disease (CD)-specific health-related quality of life (HRQOL) questionnaire would add value to CD follow-up visits; we compared patients' self-reported CD-specific HRQOL with the physician's report provided during a regular CD follow-up visit in children and young adults. METHODS: A cross-sectional study in the control group of a study on self-management in CD (CoelKids). Eligible patients had CD for ≥1 year and were 25 years or younger. They completed a CD-specific HRQOL questionnaire (CDDUX) after their regular follow-up visit. Their physicians were unaware of the present study's objectives or self-reported HRQOL. PRIMARY OUTCOME: agreement between physician-reported and self-reported HRQOL. SECONDARY OUTCOMES: patient variables predicting a discrepancy between reports, or a lower HRQOL. RESULTS: Physician-reported HRQOL was available in 70 of 78 enrolled patients. The self-reported and physician-reported HRQOL were concordant in 30 of 70 (K = 0.093), 6 of them had a poor self-reported HRQOL. Reports were discrepant in 40 of 70; all 40 self-reported a poor HRQOL. Discrepancies occurred more frequently in patients with a disease duration <9 years (32/40 with discrepant reports were diagnosed <9 years ago vs 17/30 with no discrepancy, P<0.001) and in females (35/40 with discrepant reports were girls versus 16 of 30 with no discrepancy, P = 0.001). Both factors were predictors of a poorer HRQOL. CONCLUSIONS: During regular CD follow-up visits, physicians did not report a poor HRQOL in 40 of 46 children and young adults with a poor self-reported HRQOL. This is consistent with previous studies examining other chronic diseases and supports the implementation of self-reported CD-specific HRQOL measurements in CD follow-up visits.

Early nutrition: prevention of celiac disease?

Celiac disease (CD) is an autoimmune disorder caused by ingestion of gluten in genetically predisposed individuals. It is a chronic, multiorgan disease in which small-intestinal mucosal damage may lead to malabsorption of nutrients. In the last years, several studies suggested a protective role of breast-feeding and/or the timing and quantity of gluten introduction in the subsequent development of CD. Especially, prolonged breast feeding during the introduction of gluten-containing feeding has been associated with a reduced risk of developing CD in infancy. The focus of this review was to present the actual knowledge of the possible preventive influence of early nutrition on the risk to develop CD.

Paneth cell hyperplasia and metaplasia in necrotizing enterocolitis.

Paneth cell dysfunction has been suggested in necrotizing enterocolitis (NEC). The aim of this study was to i) study Paneth cell presence, protein expression, and developmental changes in preterm infants with NEC and ii) determine Paneth cell products and antimicrobial capacity in ileostomy outflow fluid. Intestinal tissue from NEC patients (n = 55), preterm control infants (n = 22), and term controls (n = 7) was obtained during surgical resection and at stoma closure after recovery. Paneth cell abundance and protein expression were analyzed by immunohistochemistry. RNA levels of Paneth cell proteins were determined by real-time quantitative RT-PCR. In ileostomy outflow fluid, Paneth cell products were quantified, and antimicrobial activity was measured in vitro. In acute NEC, Paneth cell abundance in small intestinal tissue was not significantly different from preterm controls. After recovery from NEC, Paneth cell hyperplasia was observed in the small intestine concomitant with elevated human alpha-defensin 5 mRNA levels. In the colon, metaplastic Paneth cells were observed. Ileostomy fluid contained Paneth cell proteins and inhibited bacterial growth. In conjunction, these data suggest an important role of Paneth cells and their products in various phases of NEC.

Threonine metabolism in the intestine of mice: loss of mucin 2 induces the threonine catabolic pathway.

OBJECTIVES: Previous studies have shown that the intestine uses a major part of the dietary threonine intake for the synthesis of the structural component of the protective intestinal mucus layer, the secretory mucin Muc2. In this context, the high intestinal demand for dietary threonine probably results from its incorporation into secretory mucins rich in threonine residues. Therefore, we compared threonine utilization in the colon of Muc2 knockout (Muc2-/-) and wild-type (Muc2+/+) mice to investigate the intestinal dietary threonine metabolism in the absence of Muc2, which results in inflammation of the colon. MATERIALS AND METHODS: Concentrations and isotopic enrichment of threonine were measured by gas chromatography-isotope ratio mass spectrometry in the serum, colon, and colonic content of mice given a bolus [U-(13)C]threonine enterally. RESULTS: We retrieved 37.8% and 40.9% of dietary threonine in Muc2 +/+ and Muc2 -/- mice, respectively, either as free or incorporated threonine. There were no major differences in the availability and concentration of free or incorporated threonine recovered in both serum and colon in both types of mice. However, the Muc2 -/- mice did show overall significantly higher threonine oxidation rates compared with Muc2 +/+ mice. CONCLUSIONS: In the absence of Muc2, dietary threonine is mainly used for constitutive protein synthesis or becomes a substrate for metabolic oxidation. This indicates that inflammation also requires high threonine amounts.

Epithelial functions of the residual bowel after surgery for necrotising enterocolitis in human infants.

OBJECTIVES: Information on epithelial functions of the residual small or colonic bowel after resection for necrotising enterocolitis (NEC) in human infants is scarce. Our aim is to evaluate epithelial functions in the intestinal resection margins of tissue obtained at bowel resection for acute NEC and consecutive stoma closure. MATERIALS AND METHODS: Epithelial morphology, proliferation, and protein expression were (immuno)histochemically studied. RESULTS: Acute NEC was associated with severe and mild epithelial damage varying from epithelial loss to fairly unaffected epithelium. Epithelial proliferation was increased both at acute NEC and at stoma closure. In acute NEC, lactase, glucose transporter-2 and -5 expression was down-regulated in severely affected epithelium, whereas sucrase-isomaltase and intestinal fatty acid binding protein expression was maintained. Goblet cells continued to express mucin 2 and trefoil factor 3, however, their numbers were decreased. Moreover, in acute NEC, Paneth cells were weakly lysozyme positive and were reduced in number. At stoma closure, expression of the above cell type-specific markers had completely been re-established. CONCLUSIONS: Residual bowel after resection for acute NEC shows a disturbed epithelial proliferation/differentiation balance. Acute NEC was associated with downregulation of distinct enterocyte-specific proteins. Because of goblet cell and Paneth cell loss in acute NEC, mucosal barrier, and defense functions may be impaired.

Small intestinal MUC2 synthesis in human preterm infants.

Mucin 2 (MUC2) is the structural component of the intestinal protective mucus layer, which contains high amounts of threonine in its peptide backbone. MUC2 synthesis rate might be a potential parameter for intestinal barrier function. In this study, we aimed to determine whether systemic threonine was used for small intestinal MUC2 synthesis and to calculate the MUC2 fractional synthetic rate (FSR) in human preterm infants. Seven preterm infants with an enterostomy following bowel resection for necrotizing enterocolitis received intravenous infusion of [U-(13)C]threonine to determine incorporation of systemic threonine into secreted MUC2 in intestinal outflow fluid. Small intestinal MUC2 was isolated using cesium chloride gradient ultracentrifugation and gravity gel filtration chromatography. MUC2-containing fractions were identified by SDS-PAGE/periodic acid-Schiff staining and Western blot analysis and were subsequently pooled. Isotopic enrichment of threonine, measured in MUC2 using gas chromatography isotopic ratio mass spectrometry, was used to calculate the FSR of MUC2. Systemically derived threonine was indeed incorporated into small intestinal MUC2. Median FSR of small intestinal MUC2 was 67.2 (44.3-103.9)% per day. Systemic threonine is rapidly incorporated into MUC2 in the small intestine of preterm infants, and thereby MUC2 has a very high synthesis rate.

Dietary protein absorption of the small intestine in human neonates.

BACKGROUND: The intestine plays a key role in the absorption of dietary proteins, which determines growth of human neonates. Bowel resection in the neonatal period brings loss of absorptive and protective surface and may consequently lead to malabsorption of dietary nutrients. However, there are no data on net dietary protein absorption of the small intestine in the period after intestinal surgery in human neonates. We therefore evaluated dietary feeding tolerance and quantified net dietary protein absorption capacity of the small intestine in human neonates in whom a temporary jejunostomy or ileostomy was created. METHODS: Seventeen patients were included in the study. We collected small intestinal outflow fluid at the level of the enterostomy weekly for 24-48 hours during weeks 3 through 6 postoperatively. Protein levels in the intestinal outflow fluid were determined by bicinchoninic acid (BCA) assay. RESULTS: In 14 patients, an enteral intake of >100 mL/kg/d was reached at a median of 17 days (range, 8-32 days) postoperatively. Three patients did not reach this level within the study period. Overall, the net dietary protein absorption capacity was 70%-90% of the total enteral protein intake. CONCLUSIONS: This study demonstrates that the dietary protein absorption capacity of the small intestine is intact in most human neonates after intestinal surgery in a very critical period of their lives. Furthermore, our results do not support the use of hydrolyzed or elemental formula in newborns with an enterostomy to improve amino acid uptake.

Does small intestinal atresia affect epithelial protein expression in human newborns?

OBJECTIVES: Bowel segments distal to a congenital intestinal obstruction have been suggested to be immature. In other words, luminal components such as amniotic fluid (before birth) and/or enteral nutrition (after birth) may be required to activate intestinal epithelial protein expression, thereby influencing epithelial differentiation. We investigated cell-type-specific protein expression proximal and distal to jejunal and ileal atresias in human newborns. PATIENTS AND METHODS: We immunohistochemically studied intestinal tissue specimens of 16 newborns who had undergone surgery for jejunal or ileal atresia. Sections were taken from both the proximal and distal sides of the atresias. RESULTS: For all patients, the enterocyte-specific markers lactase, sucrase-isomaltase, sodium glucose cotransporter 1, glucose transporters 2 and 5, intestinal fatty acid-binding protein and alkaline phosphatase were expressed at a mean 3 +/- 1 days after birth, both proximal and distal to jejunal and ileal atresias. Expression of goblet cell-specific markers mucin 2 and trefoil factor 3 and that of the Paneth cell marker lysozyme was maintained at either side of the atretic segment. CONCLUSIONS: With respect to the markers used, the human small intestinal epithelium is already differentiated shortly after birth. The absence of intestinal continuity in case of a jejunal or ileal atresia does not affect epithelial protein expression. This would seem to indicate that the developing small intestinal epithelium matures independently of luminal components.

Intestinal amino acid metabolism in neonates.

The portal-drained viscera (stomach, intestine, pancreas and spleen) have a much higher rate of both energy expenditure and protein synthesis than can be estimated on the basis of their weight. A high utilization rate of dietary nutrients by the portal-drained viscera might result in a low systemic availability which determines whole-body growth. From studies in our multiple catheterized piglet model, we conclude that more than half of the dietary protein intake is utilized within the portal-drained viscera and that amino acids are a major fuel source for the visceral organs. Specific stable isotope studies reveal that there are large differences in the utilization rate amongst the different amino acids. The majority of the results obtained from the piglet studies can be extrapolated to the human (preterm) infant. First-pass, splanchnic uptake of lysine and threonine differ substantially, while non-essential amino acids are oxidized to a great extend in the human gut. Overall, these studies indicate that gut amino acid metabolism has a great impact on systemic availability and hence growth in the neonate.

Threonine utilization is high in the intestine of piglets.

The whole-body threonine requirement in parenterally fed piglets is substantially lower than that in enterally fed piglets, indicating that enteral nutrition induces intestinal processes in demand of threonine. We hypothesized that the percentage of threonine utilization for oxidation and intestinal protein synthesis by the portal-drained viscera (PDV) increases when dietary protein intake is reduced. Piglets (n = 18) received isocaloric normal or protein-restricted diets. After 7 h of enteral feeding, total threonine utilization, incorporation into intestinal tissue, and oxidation by the PDV, were determined with stable isotope methodology [U-(13)C threonine infusion]. Although the absolute amount of systemic and dietary threonine utilized by the PDV was reduced in protein-restricted piglets, the percentage of dietary threonine intake utilized by the PDV did not differ between groups (normal protein 91% vs. low protein 85%). The incorporation of dietary threonine into the proximal jejunum was significantly different compared with the other intestinal segments. Dietary, rather than systemic threonine was preferentially utilized for protein synthesis in the small intestinal mucosa in piglets that consumed the normal protein diet (P < 0.05). Threonine oxidation by the PDV was limited during normal protein feeding. In protein-restricted pigs, half of the total whole-body oxidation occurred in the PDV. We conclude that, in vivo, the PDV have a high obligatory visceral requirement for threonine. The high rate of intestinal threonine utilization is due mainly to incorporation into mucosal proteins.