The efficacy of a hyaluronate-carboxymethylcellulose bioresorbable membrane that reduces postoperative adhesions is increased by the intra-operative co-administration of a neurokinin 1 receptor antagonist in a rat model.

BACKGROUND: Bioresorbable membranes composed of hyaluronic acid and carboxymethylcellulose (HA/CMC) are the most effective method to prevent intra-abdominal adhesions; however, their efficacy may be limited to the site of application. Previous studies in our laboratory have shown that the intraperitoneal administration of a neurokinin-1 receptor antagonist (NK-1RA) reduces adhesions; however, the co-administration of HA/CMC plus an NK-1RA has not been studied. METHODS: Adhesions were induced in rats by creating ischemic buttons on the peritoneum. Rats received NK-1RA, HA/CMC, HA/CMC+NK-1RA or saline intraperitoneally at surgery. The HA/CMC was applied either bilaterally over all ischemic buttons or unilaterally over half the ischemic buttons. Animals were sacrificed and adhesions quantified at 7 days. Peritoneal fluid was collected at 24 hours to measure peritoneal tissue plasminogen activator (tPA) activity using a bioassay. RESULTS: The bilateral placement of HA/CMC alone reduced adhesions by 62% (P < .05) while the NK-1RA when administered alone reduced adhesions by 45% (P < .05), both groups compared with saline controls. The bilateral placement of HA/CMC+ NK-1RA decreased adhesions by 86% (P < .05) compared with saline controls and by 70% (P < .05) compared with either HA/CMC or NK-1RA alone. Unilateral application of HA/CMC resulted in a 41% decrease (P < .05) in adhesions where placed compared with the distal unprotected buttons in the same animal. However, the unilateral placement of HA/CMC+NK-1RA reduced adhesions by nearly 75% (P < .05) at the site of HA/CMC application compared with HA/CMC + saline, and by 45% (P < .05) at the distal unprotected buttons compared with saline controls. HA/CMC and the NK-1RA alone as well as HA/CMC+NK-1RA increased peritoneal tPA activity by 124%, 432%, and 192%, respectively (P < .05) compared with saline controls. CONCLUSION: The co-administration of HA/CMC plus NK-1RA not only increases the efficacy of the membrane at the site of application, but significantly reduces adhesions formation at distal unprotected sites. This combination may represent an emerging concept in more effective adhesion prevention throughout the peritoneum.

Practical limitations of bioresorbable membranes in the prevention of intra-abdominal adhesions.

INTRODUCTION: Intra-abdominal adhesions are a significant source of postoperative morbidity. Bioresorbable barriers composed of hyaluronic acid and carboxymethylcellulose (HA/CMC) reduce adhesion formation by physically separating injured or healing peritoneal surfaces. To assess whether the efficacy of a physical barrier can extend beyond the site of application, we evaluated the effectiveness of an HA/CMC barrier in preventing adhesions distal to the site of placement. METHODS: Adhesions were induced in rats by creating peritoneal ischemic buttons on either side of a midline incision. An HA/CMC barrier (Seprafilm Genzyme) was intraoperatively placed either under the midline incision, unilaterally over half the ischemic buttons, or bilaterally over all ischemic buttons. Control buttons received no HA/CMC. On day 7 adhesions were scored. In similar experiments, peritoneal fluid was collected at 24 h to assess the effects of HA/CMC on tissue plasminogen activator activity. RESULTS: Placement of HA/CMC under the midline incision did not reduce adhesion formation to distal ischemic buttons (72 +/- 7%) compared to controls (80 +/- 8%). Unilateral placement of HA/CMC significantly (p < 0.05) reduced adhesion formation to those ischemic buttons over which the barrier was applied (35 +/- 7%) compared to both contralateral (83 +/- 9%) and control (80 +/- 8%) ischemic buttons. The bilateral application of HA/CMC also significantly (p < 0.05) reduced adhesion formation to all ischemic buttons compared to controls (22 +/- 7% vs. 66 +/- 7%, respectively). HA/CMC did not affect peritoneal tPA activity. CONCLUSIONS: Effective adhesion reduction by the physical barrier HA/CMC appears to be limited to the site of application in this rat model. Despite the presence of a bioresorbable membrane at predicted sites of adhesion formation in the peritoneal cavity, adhesions readily form to distal unprotected sites.

An FDA approved neurokinin-1 receptor antagonist is effective in reducing intraabdominal adhesions when administered intraperitoneally, but not orally.

INTRODUCTION: Postoperative adhesions pose a continued healthcare problem. We previously demonstrated that intraperitoneal (i.p.) administration of a neurokinin-1 receptor antagonist (NK-1RA) at surgery reduces intraabdominal adhesions in rats. The NK-1RA aprepitant (Emend, Merck) is clinically approved for preventing postoperative nausea and vomiting; however, its effects on adhesion formation are unknown. Thus, we determined the effects of i.p. and oral administration of aprepitant on adhesion formation in a rat model. METHODS: Adhesions were surgically induced in rats that were randomized to receive either one or five oral preoperative doses or a single intraoperative i.p. dose of aprepitant (50 mg/kg). Adhesions were scored at 7 days. In similar experiments using i.p. dosing, animals were sacrificed at 24 h and peritoneal fluid, and tissue were collected to assess fibrinolytic activity and tissue plasminogen activator (tPA) and plasminogen activator inhibitor-1 (PAI-1) mRNA levels, respectively. RESULTS: I.p. aprepitant reduced adhesion formation by 33% (p < 0.05) compared with controls while oral aprepitant had no effect. Compared to controls i.p. aprepitant reduced tPA activity by 55% (p < 0.05), increased PAI-1 mRNA levels by 140% (p < 0.05), and had no affect on tPA mRNA levels. CONCLUSION: These data suggest that aprepitant maybe a useful pharmacologic agent for reducing adhesion formation clinically.

The Arabidopsis thaliana CUTA gene encodes an evolutionarily conserved copper binding chloroplast protein.

The Arabidopsis thaliana CUTA gene encodes a 182-amino-acid-long putative precursor of a chloroplast protein with high sequence similarity to evolutionarily conserved prokaryotic proteins implicated in copper tolerance. Northern analysis indicates that AtCUTA mRNA is expressed in all major tissue types. Analysis of cDNA clones and RT-PCR with total mRNA revealed alternative splicing of AtCUTA by retention of an intron. The intron-containing mRNA encodes a truncated 156-amino-acid protein as a result of stop codons in the included intron. The sequence of AtCutAp encoded by the fully spliced transcript suggests that the precursor consists of three domains: an N-terminal chloroplast transit sequence of 70 residues, followed by a domain with prokaryotic signal-sequence-like characteristics and finally the most conserved C-terminal domain. The N-terminal chloroplast transit sequence was functional to route a passenger protein into isolated pea chloroplasts with possible sorting to the envelope. Chloroplast localization was confirmed by Western blot analysis of isolated and fractionated chloroplasts. Recombinant AtCutA protein was expressed in Escherichia coli without the N-terminal 70-amino-acid chloroplast transit sequence. This recombinant AtCutAp was routed to the bacterial periplasm of E. coli. Purified recombinant AtCutAp is tetrameric and selectively binds Cu(II) ions with an affinity comparable to that reported for mammalian prion proteins.