Effect of alpha-trinositol on secretion induced by Escherichia coli ST-toxin in rat jejunum.

AIM: d-myo-inositol-1,2,6-trisphosphate (alpha-trinositol, PP56), is a synthetic isomer of the intracellular second messenger, d-myo-inositol-1,4,5-trisphospahate. The pharmacological actions of alpha-trinositol include potent anti-inflammatory properties and inhibition of the secretion induced by cholera toxin and obstructive ileus. In the present study, we investigated whether alpha-trinositol was able to influence the secretion induced by heat-stable ST-toxin from Escherichia coli in the rat jejunum. METHODS: A midline abdominal incision was performed in anaesthetized male Sprague-Dawley rats and a 6-7 cm long jejunal segment was isolated with intact vascular supply and placed in a chamber suspended from a force displacement transducer connected to a Grass(R) polygraph. Intestinal net fluid transport was continuously monitored gravimetrically. Crystalline ST-toxin (120 mouse units) was introduced into the intestinal lumen and left there for the rest of the experiment. When a stable secretion was observed, alpha-trinositol (60 mg kg-1 h-1) or saline were infused during 2 h, followed by a 2-h control period. RESULTS: alpha-Trinositol induced a significant (P < 0.001) inhibition of ST-toxin secretion within 30 min, lasting until 2 h after infusion had stopped. The agent also moderately increased (P < 0.05) net fluid absorption in normal jejunum. Mean arterial pressure (P < 0.001) and heart rate (P < 0.001) were reduced by alpha-trinositol. CONCLUSION: The inhibition by alpha-trinositol of ST-toxin induced intestinal secretion is primarily secondary to inhibition of secretory mechanisms and only to lesser extent due to increased absorption. The detailed mechanisms of action have not been clarified but may involve suppression of inflammation possibly by means of cellular signal transduction.

Effect of inositol-trisphosphate on fluid transport and protein extravasation in the obstructed small bowel.

BACKGROUND: Small-bowel obstruction is characterized by accumulation of fluid in the obstructed intestine. A pronounced inflammation in the obstructed gut wall has been shown to play an important role in the pathogenesis of the profuse fluid losses. alpha-Trinositol (D-myo-inositol-1,2,6-trisphosphate; PP56) has potent anti-inflammatory as well as antisecretory properties. The effects of alpha-Trinositol on inflammation and fluid losses in the obstructed small intestine are examined. METHODS: A total obstruction of the proximal part of the rat jejunum was induced during 18 h by thread ligation. A small segment of the obstructed intestine, with intact vascular and nervous supply, was placed in a chamber suspended from a force displacement transducer allowing for continuous registration of net fluid transport on a Grass polygraph. Three groups were included. One group (n = 12) received low-dose alpha-Trinositol (bolus: 2 mg kg(-1); IV infusion: 10 mg kg(-1) min(-1)), a second group (n = 10) received high-dose alpha-Trinositol (bolus: 12 mg kg(-1); IV infusion: 60 mg kg(-1) min(-1)), while a control group (n = 9) received corresponding volumes of isotonic saline (bolus: 0.5 ml; IV infusions 15 microl min(-1)). Quantitative measurement of extra-vasated Evans blue albumin in the obstructed jejunum was used as a marker of inflammation. RESULTS: High-dose alpha-Trinositol induced a significant (P < 0.001) inhibition of net fluid secretion, while low-dose alpha-Trinositol had no significant effect versus saline. In contrast, both doses of alpha-Trinositol induced significant inhibition of EB-albumin leakage (P < 0.05). CONCLUSION: High-dose alpha-Trinositol is a potent inhibitor of fluid secretion in obstructive ileus, most probably involving an anti-inflammatory mechanism.

A new technique for the analysis of endogenous mediators released following thermal injury.

Few techniques today enable us to measure the complex processes taking place inside a burn wound in vivo. The present in vivo technique was based on a standardised burn model in rat skin. A partial- or full-thickness burn was induced and resulted in a gelatinous oedema located between the skin and the underlying rectus muscle. The oedema has distinct borders to the surrounding connective tissue and is separated and removed easily for further analysis. Myeloperoxidase (MPO) activity used as indicator of neutrofil infiltration was increased significantly in the burn oedema versus non-burned skin. Leukocyte metabolic activity was high as shown by significantly higher free radical formation (ESR) in the oedema than in surrounding burned and non-burned tissue. Leukocyte viability measured by Trypan blue stain was 70% in the oedema of full-thickness burns. In order to decide whether processes taking place in the oedema communicate freely with systemic circulation, we conducted a number of experiments. Results show in burned animals in vivo that intravenous administration of indomethacin induced a strong inhibition of PGE(2) in the burn oedema as compared with saline but, as expected, had no significant effect on LTB(4) synthesis. In conclusion, the present technique allows us to analyse the processes taking place inside the burn wound in vivo and to evaluate the effects of various agents on these processes.

Importance of vasoactive intestinal polypeptide in the regulation of burn perfusion.

Vasoactive intestinal polypeptide is one of the body's most potent vasodilators and has been shown to increase blood flow in a number of tissues. Its effects on postburn skin perfusion and progressive ischemia was investigated in rats exposed to partial- and full-thickness experimental skin burns. Systemic administration of VIP elicited a significant drop in mean arterial blood pressure versus saline (p<0.001) and VIP antiserum (p<0.001) both in burned and nonburned animals. VIP also decreased heart rate versus saline (p<0.05) and anti-VIP (p<0.001) in nonburned and burned animals. In contrast, VIP antiserum significantly increased blood pressure (p<0. 001) and heart rate (p<0.001) versus saline in all the groups. Skin perfusion in normal skin was significantly impaired by VIP infusions as compared to saline (p<0.01) while VIP-antiserum did not differ significantly from saline. Similarly, VIP significantly reduced blood flow versus saline-treatment in partial-thickness (p<0.01) and full-thickness burns (p<0.05) while VIP-antiserum had no significant effect on skin perfusion in any of the burned groups as compared to saline treatment. The present results show that VIP is directly involved in general cardiovascular control but plays a minor role in the maintenance of skin perfusion following a thermal injury as suggested by the lack of effect of VIP-antiserum. In contrast, exogenous administration of VIP significantly and dramatically impaired skin perfusion in normal and burned skin probably by increasing blood flow in organs of higher priority such as the brain and heart and concomitantly inducing a pronounced vasoconstriction in the skin, probably as a result of increased sympathetic effect on peripheral organs in order to maintain blood pressure.

Role of vasoactive intestinal polypeptide in burn-induced oedema formation.

Vasoactive intestinal polypeptide has been demonstrated to lack inherent effects on capillary permeability, but also to potentiate the oedema promoting actions of other inflammatory mediators or even to strongly reduce organ damage and subsequent oedema in ischemic models of the lung and heart. This study investigated the role of VIP on oedema in partial- and full-thickness skin burns of anaesthetised rats in vivo by spectrophotometrical quantification of Evans blue albumin. Results show that systemic VIP elicited a significant drop in mean arterial blood pressure versus saline (p<0. 001) and VIP antiserum (p<0.001) both in burned and non-burned animals. VIP also decreased heart rate versus saline (p<0.05) and anti-VIP (p<0.01) in non-burned and burned animals. EB-albumin in normal skin was significantly inhibited by VIP as compared to saline (p<0.05), but did not differ significantly from VIP-antiserum. A significant inhibition of EB-albumin extravasation versus saline was also seen following administration of VIP-antiserum (p<0.01). Similarly, VIP significantly reduced EB-albumin extravasation versus saline treatment in partial-thickness (p<0.01) and full-thickness burns (p<0.001), while VIP-antiserum had no significant effect on skin perfusion in any of the burned groups as compared to saline treatment. The present results show that systemic VIP is a potent inhibitor of burn oedema. This effect could be secondary to constriction of skin vessels as a result of VIP-induced systemic hypotension or be mediated by the interaction of VIP with other oedema promoting mediators released following a thermal trauma to the skin.

Importance of nitric oxide in the regulation of burn oedema, proteinuria and urine output.

Burn injuries trigger a pronounced inflammatory response in the burned skin, resulting in oedema formation and impaired circulation. This response involves activation of the nitric oxide (NO) synthetic pathway, which could play a key role in the complex hemodynamic and hemostatic changes occurring as a result of a burn trauma. The results presented in full-thickness skin burns of rats show that the NO-precursor, L-arginine (n = 10), inhibit burn-induced plasma extravasation as compared to saline-treated burned controls (n = 10) (p<0.001) to a level not significantly different from nonburned animals. Administration of the NO-synthase inhibitor. NG-nitro-L-arginine (L-NNA) (n = 10), did not significantly influence burn extravasation compared to burned controls. Accumulated urine volume 90 min post-burn increased ten-fold in burned animals treated with L-arginine compared to saline-treated burned controls (p<0.001) and nonburned animals (p<0.001), while L-NNA had no significant effect on diuresis. A significantly increased proteinuria occurred in L-arginine treated burned animals as compared to burned controls and nonburned controls (p<0.001), whereas L-NNA did not significantly influence the leakage of protein in the urine. Activation of NO synthesis significantly suppresses burn edema and strongly increases diuresis along with increased proteinuria.

Role of nitric oxide in the control of burn perfusion.

Vascular changes following deep skin burns are characterised by vasoconstriction and progressive ischemia. Nitric oxide (NO) has been shown to be a potent regulator of vascular smooth muscle tone and tissue perfusion. We assessed the importance of NO on post-burn skin perfusion in rats using laser Doppler. The present results show that neither the NO-synthase inhibitor, NG-nitro-L-arginine (L-NNA) (n = 6) nor the NO precursor, L-arginine, significantly influenced skin perfusion in nonburned skin compared to saline-treated animals. In the area of full-thickness skin burn, neither L-arginine (n = 6) nor L-NNA (n = 6) had significant influence on post-burn perfusion compared to saline-treated controls (n = 6). Administration of L-NNA (n = 6) significantly impaired skin perfusion in the area adjacent to the contact burn representing a partial-thickness burn, while the NO precursor, L-arginine (n = 6) had no significant effect on burn perfusion as compared to saline-treated controls (n = 6). In conclusion, impairment of perfusion in a full thickness burn following administration of NO-synthase inhibitor suggests that nitric oxide is involved in the mechanisms responsible for maintaining adequate circulation post-burn. The lack of additional improvement of perfusion in response to L-arginine may suggest that NO synthesis in response to the thermal trauma is already at a peak.