Efficacy and Safety of Glutamine-supplemented Parenteral Nutrition in Surgical ICU Patients: An American Multicenter Randomized Controlled Trial.

OBJECTIVE: To determine whether glutamine (GLN)-supplemented parenteral nutrition (PN) improves clinical outcomes in surgical intensive care unit (SICU) patients. SUMMARY BACKGROUND DATA: GLN requirements may increase with critical illness. GLN-supplemented PN may improve clinical outcomes in SICU patients. METHODS: A parallel-group, multicenter, double-blind, randomized, controlled clinical trial in 150 adults after gastrointestinal, vascular, or cardiac surgery requiring PN and SICU care. Patients were without significant renal or hepatic failure or shock at entry. All received isonitrogenous, isocaloric PN [1.5 g/kg/d amino acids (AAs) and energy at 1.3× estimated basal energy expenditure]. Controls (n = 75) received standard GLN-free PN (STD-PN); the GLN group (n = 75) received PN containing alanyl-GLN dipeptide (0.5 g/kg/d), proportionally replacing AA in PN (GLN-PN). Enteral nutrition (EN) was advanced and PN weaned as indicated. Hospital mortality and infections were primary endpoints. RESULTS: Baseline characteristics, days on study PN and daily macronutrient intakes via PN and EN, were similar between groups. There were 11 hospital deaths (14.7%) in the GLN-PN group and 13 deaths in the STD-PN group (17.3%; difference, -2.6%; 95% confidence interval, -14.6% to 9.3%; P = 0.66). The 6-month cumulative mortality was 31.4% in the GLN-PN group and 29.7% in the STD-PN group (P = 0.88). Incident bloodstream infection rate was 9.6 and 8.4 per 1000 hospital days in the GLN-PN and STD-PN groups, respectively (P = 0.73). Other clinical outcomes and adverse events were similar. CONCLUSIONS: PN supplemented with GLN dipeptide was safe, but did not alter clinical outcomes among SICU patients.

The gastrin-releasing peptide analog bombesin preserves exocrine and endocrine pancreas morphology and function during parenteral nutrition.

Stimulation of digestive organs by enteric peptides is lost during total parental nutrition (PN). Here we examine the role of the enteric peptide bombesin (BBS) in stimulation of the exocrine and endocrine pancreas during PN. BBS protects against exocrine pancreas atrophy and dysfunction caused by PN. BBS also augments circulating insulin levels, suggesting an endocrine pancreas phenotype. While no significant changes in gross endocrine pancreas morphology were observed, pancreatic islets isolated from BBS-treated PN mice showed a significantly enhanced insulin secretion response to the glucagon-like peptide-1 (GLP-1) agonist exendin-4, correlating with enhanced GLP-1 receptor expression. BBS itself had no effect on islet function, as reflected in low expression of BBS receptors in islet samples. Intestinal BBS receptor expression was enhanced in PN with BBS, and circulating active GLP-1 levels were significantly enhanced in BBS-treated PN mice. We hypothesized that BBS preserved islet function indirectly, through the enteroendocrine cell-pancreas axis. We confirmed the ability of BBS to directly stimulate intestinal enteroid cells to express the GLP-1 precursor preproglucagon. In conclusion, BBS preserves the exocrine and endocrine pancreas functions during PN; however, the endocrine stimulation is likely indirect, through the enteroendocrine cell-pancreas axis.

Gut Lymphocyte Phenotype Changes After Parenteral Nutrition and Neuropeptide Administration.

OBJECTIVE: To define gut-associated lymphoid tissue (GALT) phenotype changes with parenteral nutrition (PN) and PN with bombesin (BBS). BACKGROUND: PN reduces respiratory tract (RT) and GALT Peyer patch and lamina propria lymphocytes, lowers gut and RT immunoglobulin A (IgA) levels, and destroys established RT antiviral and antibacterial immunity. BBS, an enteric nervous system neuropeptide, reverses PN-induced IgA and RT immune defects. METHODS: Experiment 1: Intravenously cannulated ICR mice received chow, PN, or PN + BBS injections for 5 days. LSR-II flow cytometer analyzed Peyer patches and lamina propria isolated lymphocytes for homing phenotypes (L-selectin and LPAM-1) and state of activation (CD25, CD44) in T (CD3)-cell subsets (CD4 and CD8) along with homing phenotype (L-selectin and LPAM-1) in naive B (IgD) and antigen-activated (IgD or IgM) B (CD45R/B220) cells. Experiment 2: Following the initial experiment 1 protocol, lamina propria T regulatory cell phenotype was evaluated by Foxp3 expression. RESULTS: Experiment 1: PN significantly reduced lamina propria (1) CD4CD25 (activated) and (2) CD4CD25LPAM-1 (activated cells homed to the lamina propria) T cells, whereas PN-BBS assimilated chow levels. PN significantly reduced lamina propria (1) IgD (naive), (2) IgDLPAM (antigen-activated homed to the lamina propria) and CD44 memory B cells, whereas PN-BBS assimilated chow levels. Experiment 2: PN significantly reduced lamina propria CD4CD25Foxp3 T regulatory cells compared with chow-fed mice, whereas PN + BBS assimilated chow levels. CONCLUSIONS: PN reduces lamina propria activated and T regulatory cells and also naive and memory B cells. BBS addition to PN maintains these cell phenotypes, demonstrating the intimate involvement of the enteric nervous system in mucosal immunity.

IL-25 improves luminal innate immunity and barrier function during parenteral nutrition.

BACKGROUND: Parenteral nutrition (PN) increases risks of infections in critically injured patients. Recently, PN was shown to reduce intestine luminal levels of the Paneth cell antimicrobial molecule secretory phospholipase A2 (sPLA2) and the goblet cell glycoprotein mucin2 (MUC2). These molecules are critical factors for innate mucosal immunity and provide barrier protection. Interleukin-4 (IL-4) and IL-13 regulate sPLA2 and MUC2 production through the IL-13 receptor. Because IL-25 stimulates IL-4 and IL-13 release and PN reduces luminal sPLA2 and MUC2, we hypothesized that adding IL-25 to PN would restore these innate immune factors and maintain barrier function. METHODS: Two days after venous cannulation, male ICR (Institute of Cancer Research) mice were randomized to receive chow (n = 12), PN (n = 9), or PN + 0.7 µg of exogenous IL-25 (n = 11) daily for 5 days. Small-intestine wash fluid (SIWF) was collected for analysis of sPLA2 activity, MUC2 density, and luminal levels of IL-4 and IL-13. Small-intestinal tissue was harvested for analysis of tissue sPLA2 activity or immediate use in an ex-vivo intestinal segment culture (EVISC) to assess susceptibility of the tissue segments to enteroinvasive Escherichia coli. RESULTS: PN reduced luminal sPLA2 (P < 0.0001) and MUC2 (P <0.002) compared with chow, whereas the addition of IL-25 to PN increased luminal sPLA2 (P < 0.0001) and MUC2 (P < 0.02) compared with PN. Tissue IL-4 and IL-13 decreased with PN compared with chow (IL-4: P < 0.0001, IL-13: P < 0.002), whereas IL-25 increased both cytokines compared with PN (IL-4: P < 0.03, IL-13: P < 0.02). Tissue levels of sPLA2 were significantly decreased with PN compared with chow, whereas IL-25 significantly increased tissue sPLA2 levels compared with PN alone. Functionally, more bacteria invaded the PN-treated tissue compared with chow (P < 0.01), and the addition of IL-25 to PN decreased enteroinvasion to chow levels (P < 0.01). CONCLUSIONS: PN impairs innate mucosal immunity by suppressing luminal sPLA2 activity and MUC2 density compared with chow. PN also increases bacterial invasion in ex-vivo tissue. Administration of exogenous IL-25 reverses this dysfunction and increases luminal sPLA2 and MUC2. PN tissue treated with IL-25 was significantly more resistant to bacterial invasion than with PN alone, suggesting that IL-25-induced effects augment the barrier defense mechanisms.

The enteric nervous system neuropeptide, bombesin, reverses innate immune impairments during parenteral nutrition.

BACKGROUND: Lack of enteral stimulation during parenteral nutrition (PN) impairs mucosal immunity. Bombesin (BBS), a gastrin-releasing peptide analogue, reverses PN-induced defects in acquired immunity. Paneth cells produce antimicrobial peptides (AMPs) of innate immunity for release after cholinergic stimulation. OBJECTIVE: Determine if BBS restores AMPs and bactericidal function during PN. METHODS: Intravenously cannulated male ICR mice were randomized to Chow, PN, or PN+BBS (15 µg 3 times daily, n = 7 per group) for 5 days. Ileum was analyzed for AMPs (Protein: sPLA2 by fluorescence, lysozyme and RegIII-γ by western andcryptdin-4 by ELISA; mRNA: all by RT-PCR). Cholinergic stimulated (100 µM bethanechol) ileal specimens assessed Pseudomonas bactericidal activity. Ileum (Chow: n = 7; PN: n = 9; PN+BBS: n = 8) was assessed for Escherichia coli invasion in ex-vivo culture. RESULTS: PN significantly decreased most AMPs versus Chow while BBS maintained Chow levels (sPLA2: Chow: 107 + 14*, PN: 44.6 + 7.2, PN+BBS: 78.7 + 13.4* Fl/min/µL/total protein; Lysozyme: Chow: 63.9 + 11.9*, PN: 26.8 + 6.2; PN+BBS: 64.9 + 13.8* lysozyme/total protein; RegIII-γ: Chow: 51.5 + 10.0*, PN: 20.4 + 4.3, PN+BBS: 31.0 + 8.4 RegIII-γ/total protein; Cryptdin-4: Chow: 18.4 + 1.5*, PN: 12.7 + 1.6, PN+BBS: 26.1 + 2.4*† pg/mg [all *P < 0.05 vs PN and †P < 0.05 vs Chow]). Functionally, BBS prevented PN loss of bactericidal activity after cholinergic stimulation (Chow: 25.3 + 3.6*, PN: 13.0 + 3.2; PN+BBS: 27.0 + 4.7* percent bacterial killing, *P < 0.05 vs PN). BBS reduced bacterial invasion in unstimulated tissue barely missing significance (P = 0.06). CONCLUSIONS: The enteric nervous system (ENS) controls AMP levels in Paneth cells during PN but mucosal protection by innate immunity requires both ENS and parasympathetic stimulation.

IL-25 improves IgA levels during parenteral nutrition through the JAK-STAT pathway.

INTRODUCTION: Parenteral nutrition (PN) impairs mucosal immunity and increases the risk of infection in part via lower IgA levels at mucosal surfaces. Transport of immunoglobulin A (IgA) across the mucosa to the gut lumen depends on the epithelial transport protein, polymeric immunoglobulin receptor (pIgR), which is reduced during PN. In vitro, studies demonstrate that IL-4 up-regulates pIgR production via Janus kinase/signal transducers and activators of transcription (JAK/STAT) signaling. Because IL-4 stimulates IgA and is reduced during PN, we hypothesized that the suppressed pIgR is a result of decreased JAK-1 and STAT-6 phosphorylation. Because IL-4 is mediated by IL-25, we also hypothesized that PN + IL-25 would restore luminal IgA by increasing phosphorylated JAK-1 and STAT-6, resulting in increased tissue pIgR and luminal IgA. METHOD: Experiment 1: 2 days after intravenous cannulation, male Institute of Cancer Research mice were randomized to chow (n = 11) or PN (n = 9). Experiment 2: 2 days after intravenous cannulation, male Institute of Cancer Research mice were randomized to chow (n = 12), PN (n = 10), or PN + 0.7 µg of exogenous IL-25 (n = 11) per day. After 5 days, distal ileum tissue was collected, homogenized, and protein extracted for JAK-STAT expression levels using a phospho-specific antibody microarray. Tissue was homogenized to measure pIgR expression via Western blot or fixed in 4% paraformaldehyde to measure pIgR expression via immunohistochemistry. Small intestinal wash fluid was collected and IgA was quantified using enzyme-linked immunosorbent assay. RESULTS: Experiment 1: PN significantly reduced phosphorylated JAK-1 and STAT-6 compared with chow. PN also decreased the tissue levels of the Th2 cytokines, IL-4 and IL-13, as well as pIgR, and luminal IgA compared with chow. Experiment 2: Exogenous administration of PN + IL-25 increased the phosphorylated JAK-1 and STAT-6 compared with PN alone. IL-25 completely restored expression of IL-13 to chow levels. IL-4, pIgR, IgA, and phosphorylated JAK-1 were significantly increased with IL-25 treatment compared with PN but failed to reach levels measured in chow. STAT-6 was significantly increased with IL-25 treatment compared with chow and PN. CONCLUSIONS: PN significantly decreases the JAK-STAT pathway by reducing levels of phosphorylated STAT-6 and JAK-1. Consistent with our previous work, sIgA, pIgR, and IL-4 decreased with PN, whereas the addition of IL-25 to PN reversed these decreases and demonstrated the role of the JAK-STAT pathway in vivo during PN.

Parenteral nutrition increases susceptibility of ileum to invasion by E coli.

BACKGROUND: Parenteral nutrition (PN), with the lack of enteral feeding, compromises mucosal immune function and increases the risk of infections. We developed an ex vivo intestinal segment culture (EVISC) model to study the ex vivo effects of PN on susceptibility of the ileum to invasion by extra-intestinal pathogenic Escherichia coli (ExPEC) and on ileal secretion of antimicrobial secretory phospholipase A2 (sPLA2) in response to the pathogen. MATERIALS AND METHODS: Study 1: Using mouse (n = 7) ileal tissue, we examined the effects of ileal region (proximal versus distal) and varying ExPEC inoculum concentrations on ex vivo susceptibility to ExPEC invasion and sPLA2 secretion. Study 2: Ten mice were randomized to oral chow or intravenous PN feeding for 5 d (n = 5/group). Using the EVISC model, we compared the susceptibility of ileal tissue to invasion by ExPEC and sPLA2 secretion in response to the pathogen. RESULTS: Study 1: The proximal ileum was more susceptible to invasion (P < 0.0001) and secreted lower amounts of sPLA2 (P = 0.0002) than the distal ileum. Study 2: Ileal tissue from PN-fed animals was more susceptible (approximately 4-fold, P = 0.018) to invasion than those from chow-fed animals. Ileal tissue from PN-fed animals secreted less sPLA2 (P < 0.02) than those from chow-fed animals. CONCLUSIONS: The data illustrate EVISC as a reproducible model for studying host-pathogen interactions and the effects of diet on susceptibility to infections. Specifically, the findings support our hypothesis that PN with the lack of enteral feeding decreases mucosal responsiveness to pathogen exposure and provides a plausible mechanism by which PN is associated with increased risk of infectious complication.

Colonic enteric nervous system analysis during parenteral nutrition.

INTRODUCTION: Parenteral nutrition (PN) is a necessary therapy used to feed patients with gastrointestinal dysfunction. Unfortunately, PN results in intestinal atrophy and changes to host immune function. PN may also induce additional effects on gut motility that we hypothesized would result from changes in the enteric nervous system. METHODS: Mice received an intravenous (i.v.) catheter and were randomized to chow (n = 5), i.v. PN (n = 6), or i.v. PN + bombesin (BBS, 15 µg/kg, 3×/d) (n = 6) for 5 d. Colons were removed and dissected to measure the length and circumference. Enteric neuronal density and neurotransmitter expression were determined by co-immunostaining whole-mount tissue with Hu and neuronal nitric oxide synthase (nNOS). RESULTS: The number of myenteric neurons expressing Hu and nNOS increased per unit length in the mid-colon during PN treatment compared with chow. This increase was abrogated by the addition of BBS to the PN regimen. However, the percentage of nNOS-expressing neurons was not significantly altered by PN. Morphometric analysis revealed a decrease in the length and circumference of the colon during PN administration that was partially normalized by supplementation of PN with BBS. A significant reduction in total fecal output was observed in PN animals compared with chow and was increased by mice receiving BBS in addition to PN. CONCLUSIONS: PN causes a constriction of the bowel wall, reducing not only the length but also the circumference of the colon. These changes cause a condensation of enteric neurons but no difference in neurotransmitter expression. BBS supplementation partially restores the constriction and increases the fecal output during PN treatment compared with PN treatment alone.

A tale of two analyses: Administrative vs primary review of nutrition support team performance.

BACKGROUND: Our pharmacy department performed a medication-use evaluation using administrative data to assess prescription of parenteral nutrition (PN). They found that 31.6% (185 of 586) of nutrition support team (NST) patients received ≤5 days of PN, whereas 120 received ≤3 days. These results raised the question of NST prescribing practices given the incidence of short-duration PN. Since our NST evaluates all PN requests, the study prompted further review to identify reasons for short duration PN. METHODS: Charts of patients receiving PN for ≤3 days in the initial study underwent an in-depth review focusing on indications, reasons for discontinuation, and protein-calorie malnutrition (PCM) at time of NST consultation. RESULTS: A total 120 of 586 patients had PN ≤3 days. PN was clearly indicated in 94 cases: 27 patients received home PN but resolved the need for admission, 11 were admitted to later discharge on PN, 18 chose alternative/palliative care soon after starting PN, and 38 were nil per os for ≥6 days because of ileus, bowel obstruction, or contraindication to enteral feeding. Of the remaining 26 patients, 15 had PCM with poor intake for ≥ 3 days, warranting PN; only nine cases had unclear indications for PN and 11 could have potentially been avoided. CONCLUSION: Administrative data implied inappropriate PN use, whereas in-depth review confirmed appropriate prescription in most patients. Reducing short-duration PN in the management of ileus or obstruction remains difficult because of variable time to symptom resolution. In-depth chart review remains the best method to assess appropriateness of PN use.

A team-based protocol and electromagnetic technology eliminate feeding tube placement complications.

OBJECTIVE: To examine whether feeding tube placement into high-risk patients using a team-based protocol and electromagnetic tube tracking reduces complications associated with blind tube placement and to evaluate safety of blind tube placement in alert, low-risk patients. BACKGROUND: Approximately 1·2 million feeding tubes with stylets are placed annually in the US. Serious complications during placement exceed the rates of retained sponges and wrong site surgery. Several suggested solutions to the problem have been proposed but none completely eliminate the serious complications and many are neither cost-effective nor practical. METHODS: In a retrospective, single center study, we compared complications after bedside feeding tube placement using a blind technique in 2005 to a hospital protocol mandating tube placement in high-risk patients by a Tube Team in 2007 using electromagnetic tracking. Outcome variables included airway placement, pneumothorax, death, and radiology resource utilization. RESULTS: The Tube Team protocol eliminated airway tube placement (0 of 1154 vs. 20 of 1822, P < 0.001), pneumothorax (0/715 vs. 11/1822, P = 0.009), and all mortality whereas improving placement (83.9% success vs. 60.5%, P<0.001) in high-risk patients compared to the 2005 study. The number of x-rays obtained per tube (1.07 +/− 0.01 vs. 1.49 +/− 0.026, P < 0.001) and need for fluoroscopy (2.1% vs. 10.9%, P < 0.001) significantly dropped with the Tube Team. A final comparison was made to low-risk patients considered acceptable for blind tube placement in 2007 due to their alertness and ability to cooperate and provide feedback during tube placement. Although no mortality occurred during blind placement in low risk, alert patients, blind placement resulted in significantly increased airway placement (3/143, p = 0.001) and pneumothorax (2 of 143, P = 0.01) compared to the Tube Team protocol. Most patients who would have required fluoroscopic placement of feeding tube due to failed blind technique had successful placement by the Team avoiding fluoroscopy. CONCLUSION: Feeding tube placement by a dedicated team using electromagnetic tracking eliminates the morbidity and mortality of this common hospital procedure. Blind placement is not acceptable in awake, alert patients.

Parenteral nutrition impairs lymphotoxin ß receptor signaling via NF-κB.

OBJECTIVE: To determine effects of (1) parenteral nutrition (PN), (2) exogenous Lymphotoxin ß receptor (LTßR) stimulation in PN animals, and (3) exogenous LTßR blockade in chow animals on NF-κB activation pathways and products: MAdCAM-1, chemokine (C-C motif) Ligand (CCL) 19, CCL20, CCL25, interleukin (IL)-4, and IL-10. BACKGROUND: LT stimulates LTßR in Peyer's patches (PP) to activate NF-κB via the noncanonical pathway. The p100/RelB precursor yields p52/RelB producing MAdCAM-1, cytokines, and chemokines important in cell trafficking. TNFα, IL-1ß, and bacterial products stimulate the inflammatory canonical NF-κB pathway producing p65/p50 and c-Rel/p50. PN decreases LTßR, MAdCAM-1, and chemokines in PP and lowers small intestinal IgA compared with chow. METHODS: Canonical (p50 and p65) and noncanonical (p52 and Rel B) NF-κB proteins in PP were analyzed by TransAM NF-κB kit after 5 days of chow or PN, 2 days of LTßR stimulation or 3 days of LTßR blockade. MAdCAM-1, chemokines, and cytokines in PP were measured by ELISA after LTßR stimulation or blockade. RESULTS: PN significantly reduced all NF-κB proteins in PP compared with chow. Exogenous LTßR stimulation during PN increased p50, p52, Rel B, MAdCAM-1, IL-4, and IL-10 in PP, but not p65, CCL19, CCL20, or CCL25 compared with PN. LTßR blockade reduced noncanonical products (p52 and Rel B), MAdCAM-1, CCL19, CCL20, CCL25, IL-4, and IL-10 but had no effect on the inflammatory pathway (p50 and p65) compared with chow. CONCLUSION: Lack of enteral stimulation during PN decreases both canonical and noncanonical NF-κB pathways in PP. LTßR stimulation during PN feeding completely restores PP noncanonical NF-κB activity, MAdCAM-1, IL-4, IL-10, and partly the canonical pathway. LTßR blockade decreases the noncanonical NF-κB activity, MAdCAM-1, chemokines, and cytokines without effect on the canonical NF-κB activity in PP.

Proinflammatory cytokine surge after injury stimulates an airway immunoglobulin a increase.

BACKGROUND: : Injury stimulates an innate airway IgA response in severely injured patients, which also occurs in mice. Tumor necrosis factor (TNF)-α and interleukin (IL)-1ß stimulate the production of polymeric immunoglobulin receptor, the protein required to transport immunoglobulin A (IgA) to mucosal surfaces. Blockade of TNF-α and IL-1ß eliminates the airway IgA response to injury. IL-6 stimulates differentiation of B cells into IgA-secreting plasma cells at mucosal sites. We investigated the local and systemic kinetics of TNF-α, IL-1ß, and IL-6 after injury in mice. We also hypothesized that injection of exogenous TNF-α, IL-1ß, and IL-6 would replicate the airway IgA response to injury. METHODS: : Experiment 1: male Institute of Cancer Research mice were randomized to uninjured controls (n = 8) or to surgical stress with laparotomy and neck incisions, with killing at 1, 2, 3, 5, or 8 hours after injury (n = 8/group). Bronchoalveolar lavage (BAL) and serum levels of TNF-α, IL-1ß, and IL-6 were analyzed by enzyme-linked immunosorbent assay. Experiment 2: male Institute of Cancer Research mice were randomized to uninjured controls (n = 6), injury (surgical stress that was similar to experiment 1 except the peritoneum was left intact, n = 6), or cytokine injection with intraperitoneal injection of recombinant TNF-α, IL-1ß, and IL-6. Animals were killed at 2 hours after injury, and nasal airway lavage and BAL IgA were analyzed by enzyme-linked immunosorbent assay. RESULTS: : Experiment 1: BAL TNF-α, IL-1ß, and IL-6 levels increased in bimodal pattern after injury at 3 hours and 8 hours versus controls (p < 0.05). Serum IL-6 did not increase at 3 hours, but did show a significant increase by 5 hours versus control (p < 0.05). Serum levels of TNF-α and IL-1ß did not change. Experiment 2: both Injury and combination TNF-α, IL-1ß, and IL-6 cytokine injection significantly increased IgA levels in airway lavage (BAL + nasal airway lavage) compared with control (p < 0.01 for both). CONCLUSIONS: : Airway levels of TNF-α, IL-1ß, and IL-6 increase in a bimodal pattern after injury with peaks at 3 hours and 8 hours, which do not correspond to serum changes. The peak at 8 hours is consistent with the known increase in airway IgA after injury. Intraperitoneal injection of a combination exogenous TNF-α, IL-1ß, and IL-6 replicates the airway IgA increase after injury. This effect is not seen with individual cytokine injections.

Role of heat shock protein and cytokine expression as markers of clinical outcomes with glutamine-supplemented parenteral nutrition in surgical ICU patients.

BACKGROUND: Nutrients, such as glutamine (GLN), have been shown to effect levels of a family of protective proteins termed heat shock proteins (HSPs) in experimental and clinical critical illness. HSPs are believed to serve as extracellular inflammatory messengers and intracellular cytoprotective molecules. Extracellular HSP70 (eHSP70) has been termed a chaperokine due to ability to modulate the immune response. Altered levels of eHSP70 are associated with various disease states. Larger clinical trial data on GLN effect on eHSP expression and eHSP70's association with inflammatory mediators and clinical outcomes in critical illness are limited. OBJECTIVE: Explore effect of longitudinal change in serum eHSP70, eHSP27 and inflammatory cytokine levels on clinical outcomes such as pneumonia and mortality in adult surgical intensive care unit (SICU) patients. Further, evaluate effect of parenteral nutrition (PN) supplemented with GLN (GLN-PN) versus GLN-free, standard PN (STD-PN) on serum eHSP70 and eHSP27 concentrations. METHODS: Secondary observational analysis of a multicenter clinical trial in 150 adults after cardiac, vascular, or gastrointestinal surgery requiring PN support and SICU care conducted at five academic medical centers. Patients received isocaloric, isonitrogenous PN, with or without GLN dipeptide. Serum eHSP70 and eHSP27, interleukin-6 (IL-6), and 8 (IL-8) concentrations were analyzed in patient serum at baseline (prior to study PN) and over 28 days of follow up. RESULTS: eHSP70 declined over time in survivors during 28 days follow-up, but non-survivors had significantly higher eHSP70 concentrations compared to survivors. In patients developing pneumonia, eHSP70, eHSP27, IL-8, and IL-6 were significantly elevated. Adjusted relative risk for hospital mortality was reduced 75% (RR = 0.25, p = 0.001) for SICU patients with a faster decline in eHSP70. The area under the receiver operating characteristic curve was 0.85 (95% CI: 0.76 to 0.94) for the final model suggesting excellent discrimination between SICU survivors and non-survivors. GLN-PN did not alter eHSP70 or eHSP27 serum concentrations over time compared to STD-PN. CONCLUSION: Our results suggest that serum HSP70 concentration may be an important marker for severity of illness and likelihood of recovery in the SICU. GLN-supplemented-PN did not increase eHSP70.

Parenteral feeding depletes pulmonary lymphocyte populations.

BACKGROUND: The effect of parenteral nutrition (PN) on lymphocyte mass in the lung is unknown, but reduced mucosal lymphocytes are hypothesized to play a role in the reduced immunoglobulin A-mediated immunity in both gut and lung. The ability to transfer and track cells between mice may allow study of diet-induced mucosal immune function. The objectives of this study are to characterize lung T-cell populations following parenteral feeding and to study distribution patterns of transferred donor lung T cells in recipient mice. METHODS: In experiment 1, cannulated male Balb/c mice are randomized to receive chow or PN for 5 days. Lung lymphocytes are obtained via collagenase digestion, and flow cytometric analysis is used to identify total T (CD3+) and B (CD45/B220+) cells. In experiment 2, isolated lung T cells from chow-fed male Balb/c mice are pooled and labeled in vitro with a fluorescent dye (carboxyfluorescein diacetate succinimidyl ester [CFSE]), and 1.1 x 10(8) CFSE+ cells (3.1 x 10(6) T cells) are transferred to chow-fed Balb/c recipients. Cells recovered from recipient lungs and intestinal lamina propria (LP) are analyzed by flow cytometry to determine CFSE/CD3+ T cells at 1, 2, and 7 days. In experiment 3, cells are transferred to PN-fed recipients. RESULTS: In experiment 1, PN significantly decreases lung T- and B-cell populations compared with chow feeding. In experiment 2, CFSE+ T-cell retention is highest on day 1 in lung and LP, and decreases on day 2. Cells are gone by day 7; 98.1% of retained donor lung T cells migrate to recipient lungs and 1.9% to the intestine on day 1. Similar results are seen in experiment 3 after transfer of cells to PN-fed recipients. CONCLUSIONS: PN reduces pulmonary lymphocyte populations consistent with impaired respiratory immunity. Transferred lung T cells preferentially localize to recipient lungs rather than intestine with maximal accumulation at 24 hours. Limited cross-talk of transferred lung T cells to the intestine indicates that mucosal lymphocyte traffic might be programmed to localize to specific effector sites.

Food fight! Parenteral nutrition, enteral stimulation and gut-derived mucosal immunity.

INTRODUCTION: Nutrition support is an integral component of modern patient care. Type and route of nutritional support impacts clinical infectious outcomes in critically injured patients. DISCUSSION: This article reviews the relationships between type and route of nutrition and gut-derived mucosal immunity in both the clinical and laboratory settings.

Parenteral nutrition induces organ specific alterations in polymeric immunoglobulin receptor levels.

BACKGROUND: Secretory immunoglobulin A (IgA) prevents pathogen adherence at mucosal surfaces to prevent infection. Polymeric immunoglobulin receptor (pIgR), located on the basolateral surface of mucosal cells, binds dimeric IgA produced by B cells with the cooperation of T cells in the lamina propria. This IgA-pIgR complex is transported apically, where it is exocytosed as secretory IgA to the mucosal surface. Our prior work shows that parenteral nutrition (PN) impairs both airway and small intestine mucosal immunity by reducing T and B cells and IgA levels. This work examines intestinal and respiratory tissue-specific pIgR responses to PN. METHODS: Cannulated male Institute of Cancer Research mice were randomized to Chow (n = 10) or PN (n = 10). After 5 days, animals were sacrificed and lavages obtained from the small intestine, lung (BAL = bronchoalveolar lavage), and nasal airways (NAL). Small intestine, lung, and nasal passage tissues were also collected. Lavage and tissue homogenate IgA levels were quantified by enzyme-linked immunosorbent assay and pIgR by Western blot. RESULTS: PN group SIL and NAL IgA levels dropped significantly compared with Chow. PN significantly reduced pIgR levels in the SI while no pIgR change was noted in nasal passages and lung pIgR actually increased with PN. Tissue homogenate IgA levels did not change with PN in the SI while levels in the nasal passage and lung decreased. CONCLUSIONS: PN impairs airway mucosal immunity by reduction in IgA available for transport rather than via a reduction in pIgR levels. In the small intestine, diminished pIgR is implicated in the deterioration of antibody-mediated mucosal immunity.

Decreased enteral stimulation alters mucosal immune chemokines.

BACKGROUND: Migration of lymphocytes into and through the mucosal immune system depends upon adhesion molecules to attract circulating cells and chemokines to stimulate diapedesis into tissues. Decreased enteral stimulation significantly reduces mucosal addressin cellular adhesion molecule-1 (MAdCAM-1) levels, an adhesion molecule critical for homing of T and B cells to Peyer's patches (PP), which reduces PP and intestinal T and B cells. We studied the effect of type and route of nutrition on tissue specific chemokines in PP (CXCL-12, -13 and CCL-19, -20 and -21), small intestine (SI; CCL-20, -25 and -28) and lung (CXCL-12, CCL-28). METHODS: Intravenously cannulated male Institute of Cancer Research (ICR) mice were randomized to chow or parenteral nutrition (PN) for 5 days. PP, SI, and lung chemokine mRNA levels were measured using real-time qRT-polymerase chain reaction, and analyzed semiquantitatively by the DeltaDeltaCt method. Protein levels were quantified using enzyme-linked immunosorbent assay (ELISA) techniques, and groups compared using Student's t-test. RESULTS: PP CXCL13 protein significantly decreased, whereas CCL21 protein increased significantly in the parenterally fed group. Parenteral feeding significantly decreased SI CCL20 and CCL 25 protein levels. CCL28 decreased significantly in the SI and lung of intravenously fed animals. mRNA levels changed in the opposite direction (compared with protein) for all chemokines except CCL28. CONCLUSIONS: Decreased enteral stimulation significantly alters key mucosal immune chemokine protein levels at multiple sites. In general, PN (and concomitant lack of enteral stimulation) results in decreased levels of chemokines that control lymphocyte migration within the mucosal immune system.

Parenteral nutrition inhibits tumor necrosis factor-alpha-mediated IgA response to injury.

BACKGROUND: Parenteral nutrition (PN) increases the incidence of pneumonia in severely injured patients compared with enteral feeding (ENT). Injury induces an innate airway IgA response in severely injured patients; similar responses occur in mice. Tumor necrosis factor-alpha (TNF-alpha) and interleukin-1 beta (IL-1beta) stimulate the production of polymeric immunoglobulin receptor (pIgR), the protein required to transport immunoglobulin A (IgA) to mucosal surfaces. We have shown that PN alters levels of lung and nasal passage IgA and several IgA-stimulating cytokines. We hypothesized that TNF-alpha and IL-1beta blockade, as well as PN, would blunt the airway IgA response to injury. METHODS: Male Institute of Cancer Research (ICR) mice were randomized to uninjured controls (n = 10) or to intra-peritoneal phosphate-buffered saline (PBS) (n = 9), antagonistic TNF-alpha antibody (100 mcg, n = 7), or antagonistic IL-1beta antibody (50 mcg, n = 8) 30 min prior to surgical stress with laparotomy and neck incisions. Mice were sacrificed at 8 h for nasal and bronchoalveolar lavage (NAL, BAL) to measure IgA by enzyme-linked immunosorbent assay. In a separate experiment, 12 mice underwent intravenous cannulation followed by chow (n = 5) or PN (n = 7) feeding for 5 days prior to the same stress and IgA measurement. RESULTS: Injury significantly increased NAL and BAL IgA (225 +/- 104 ng) compared with baseline (145 +/- 38 ng; p = 0.01). Blockade of TNF-alpha eliminated the innate airway IgA response to injury (130 +/- 47 ng; p = 0.01), whereas IL-1beta blockade blunted and PN eliminated it completely. CONCLUSIONS: Tumor necrosis factor-alpha is involved in the respiratory IgA immune response to injury. Both TNF-alpha blockade and PN impair this innate response, and blockade of IL-1beta impairs it to a degree. We hypothesize that these cytokines blunt this response via their known effects on the polymeric immunoglobulin receptor (pIgR), whereas the PN-induced deficit likely is multifactorial.

Injury stimulates an innate respiratory immunoglobulin a immune response in humans.

BACKGROUND: Secretory immunoglobulin A (SIgA) is the specific immune antibacterial defense. Since pneumonia frequently complicates the course of trauma patients, we studied early airway immune responses after injury. METHODS: Twelve severely injured, intubated (expected for >/=5 d) patients had tracheal and bilateral lung lavage (BAL) within 30 hours of injury (n = 12). Epithelial lining fluid (ELF) volume and SIgA were measured by urea dilution and enzyme-linked immunosorbent assay (ELISA), respectively. Control BAL specimens were obtained from eight healthy elective surgical patients. Anatomically based comparisons were made between groups with Welch's unpaired t test. To verify human data, 30 male mice received no injury (time 0, n = 7) or injury with abdominal and neck incisions and were killed for airway IgA at 4 (n = 7), 8 (n = 8), and 24 (n = 8) hours. Analysis of variance (ANOVA) and Fisher's protected least significant difference testing was used to analyze animal data. RESULTS: Initial trauma patient SIgA concentration (SIgA/mL ELF) increased compared with control in the lungs bilaterally (p < 0.05 both right and left). ELF volume was significantly higher in the right lung (p = 0.02) and just missed statistical significance (p = 0.07) on the left. Mouse IgA increased 8 hours after stress (p < 0.05 versus 0, 4, and 24 hours) and returned to normal by 24 hours. CONCLUSION: A previously unrecognized innate human airway mucosal immune response with increased airway SIgA and ELF occurs after severe injury and is reproducible experimentally. This accessible, quantifiable human response allows study of clinical strategies to reduce infections via mucosal immune therapies.

Beneficial effect of enteral feeding.

The last 4 decades have seen an explosion in nutritional research investigating both clinical and laboratory issues occurring in diverse groups of patients who cannot maintain a normal oral diet. Over the past 25 years, researchers have investigated how the administration of macro- and micronutrients via the gastrointestinal tract provides additional benefit over parenteral administration of similar nutrients. The administration of enteral feeding provides effects that are far beyond those of merely administering macro- and micronutrients. Rather, the processing of nutrients via the gastrointestinal tract stimulates a complex response that has implications for body composition and for immunologic integrity. Route and type of nutrition are important aspects of successful patient recovery.