Plasma renin activity and the renal response to nitric oxide synthesis inhibition.

Inhibition of systemic endothelium-derived relaxing factor (EDRF) synthesis with L-Nw-nitroarginine (L-NAME) results in decreased RBF, which can be reversed by acute blockade of angiotensin II (AII). Because AII is particularly elevated in the renal circulation, it was hypothesized that the degree of renal vasoconstriction produced by L-NAME in Inactin-anesthetized rats is related to PRA. To test this, PRA was chronically increased or suppressed by the manipulation of dietary sodium (eating 0.03% sodium chow or deoxycorticosterone acetate plus drinking 1% NaCl, respectively). After 10 days, rats were anesthetized for determination of blood pressure (BP) and RBF before and after L-NAME (10 mg/kg body wt). In rats with high PRA (61.6 +/- 10.4 ng of angiotensin I [Al]/mL/h; N = 8), L-NAME increased BP by 29 +/- 2 mm Hg (from 110 +/- 4 to 139 +/- 5 mm Hg; P < 0.001), decreased RBF by 27% (from 7.9 +/- 0.3 to 5.8 +/- 0.3 mL/min/g kidney wt; P < 0.001), and increased renal vascular resistance (RVR) by 67% (from 14.5 +/- 0.9 to 24.2 +/- 1.1 resistance units [RU]; P < 0.001). When rats with high PRA (N = 8) were treated with 10 mg/kg body wt of DuP 753, on AII receptor antagonist, L-NAME similarly increased BP by 30 +/- 5 mm Hg (from 81 +/- 3 to 111 +/- 5; P < 0.001) but RBF did not change and RVR increased by only 31% (from 10.9 +/- 0.8 to 13.3 +/- 0.7 RU; P < 0.005).(ABSTRACT TRUNCATED AT 250 WORDS)     

Impaired renal blood flow autoregulation in two-kidney, one-clip hypertensive rats is caused by enhanced activity of nitric oxide

Increases in renal perfusion pressure will induce shear stress-mediated nitric oxide (NO) release, which could oppose autoregulation of renal blood flow (RBF). Although cardiac, cerebral, and mesenteric autoregulation is enhanced during nitric oxide (NO) synthesis inhibition, this has not been reported for renal autoregulation of blood flow. In the present study, the lower limit and efficiency of RBF autoregulation (as assessed by the degree of compensation) were studied before and during NO inhibition in normotensive Sprague Dawley rats (control; n = 9) and in the non-clipped kidney of two-kidney, one-clip Goldblatt hypertensive animals (2K1C; n = 9; 3 wk; 0.25-mm silver clip). In both groups, renal autoregulation curves were obtained before and during infusion of N(G) -nitro-L-arginine (L-NNA) (bolus 1.5 mg/kg intravenously, infusion 10 microg/kg per min intravenously), using a transit-time flow probe around the left renal artery. In control rats, mean arterial pressure (MAP) increased, RBF decreased, and renal vascular resistance (RVR) increased in response to L-NNA infusion. The lower limit of autoregulation in control animals did not significantly change during L-NNA infusion (78 +/- 3 to 70 +/- 2 mmHg). The degree of compensation in these rats slightly increased during L-NNA infusion, however, this was only significant below 90 mmHg. The 2K1C rats had elevated MAP under baseline conditions. L-NNA infusion resulted in a decrease in RBF and an increase in MAP and RVR. During L-NNA infusion, RVR in 2K1C rats greatly exceeded RVR in control rats. A significant decrease was observed in the lower limit of autoregulation from 85 +/- 3 to 72 +/- 5 mmHg (P < 0.05). In the contralateral kidney of 2K1C rats, the degree of compensation was lower than in control rats under baseline conditions. L-NNA infusion resulted in significantly higher degrees of compensation compared to baseline. In conclusion, the contralateral kidney displayed a high NO dependency, as RBF greatly decreased and RVR dramatically increased in response to L-NNA infusion. The contralateral kidney of 2K1C rats exhibited impaired RBF autoregulation, which was improved by NO inhibition, as judged from a decrease in the lower limit of autoregulation and an increase in the degree of compensation. This study indicates that perfusion pressure-dependent NO release can oppose autoregulation in the kidney. However, the enhanced influence of NO on pressure-dependent RBF may facilitate the preservation of renal function in the nonclipped kidney of 2K1C rats.     

Effects of L-arginine and L-NAME on the renal function in hypertensive and normotensive subjects

BACKGROUND/AIM: Renal vasodilation in response to L-arginine has been reported to be diminished in hypertensive (HT) subjects. If this diminished renal vasodilator response indicates disturbance of the renal NO pathway, a diminished renal vasoconstrictor response to NO synthase inhibition may be present in HT subjects as well. The present study was conducted to compare the effects of L-arginine and N(G)-nitro-L-arginine methyl ester (L-NAME) on renal and systemic hemodynamics between HT and normotensive (NT) subjects. METHODS: The responses of renal and systemic vascular resistances (RVR and SVR) and plasma noradrenaline and renin (NOR and PRA) to systemic NO stimulation and inhibition were studied in patients with grade 1 essential HT and age- and sex-matched NT subjects. On separate occasions, after baseline values were obtained, 40-min randomly administered intravenous infusions of L-arginine (12.5 mg.kg(-1).min(-1)) or L-NAME (0.0125 mg.kg(-1).min(-1)) were given. RESULTS: Baseline values of RVR (129 +/- 21 and 162 +/- 10 resistance units) and SVR (15.1 +/- 4.3 and 21.6 +/- 5.1 resistance units) were higher (p < 0.01) in HT than in NT subjects, whereas the baseline values of NOR and PRA were similar. Infusion of L-arginine caused similar decrements in SVR (29 +/- 10 and 31 +/- 11%), but the decrease in RVR was smaller (22 +/- 8 and 35 +/- 12%, respectively; p < 0.05) in HT than in NT subjects. In response to L-NAME, the increments in RVR (66 +/- 10 and 61 +/- 25%) and SVR (36 +/- 21 and 34 +/- 18%) were similar in HT and NT subjects. In both groups, infusion of L-arginine was associated with similar increments, whereas infusion of L-NAME was associated with similar decrements in NOR and PRA. CONCLUSIONS: This study confirms the smaller renal vasodilator response to L-arginine in HT than in NT subjects. Whether this is caused by a disturbance of the renal NO pathway remains doubtful considering the observed similar L-NAME-induced increments in RVR and SVR in the two groups of subjects.     

Influence of the rate of infusion on cyclosporine nephrotoxicity in the rat

The effect of the rate of infusion of single and multiple doses of cyclosporine (CsA) on renal function was evaluated in Sprague-Dawley rats. CsA was dissolved in cremophore (Crem) or Tween 80 (Tween) and infused over consecutive 10-min periods at doses of 10, 20, 30 and 40 mg/kg. CsA-Crem and CsA-Tween produced similar and progressive changes in MAP, RBF, and RVR. By the end of the infusion, the mean values (% of control) of MAP (122 +/- 16% and 131 +/- 22%), RBF (56 +/- 11% and 66 +/- 20%), and RVR (222 +/- 38% and 232 +/- 134%) were significantly different from their respective preinfusion values. Infusion of Crem alone resulted in renal vasodilation at low doses and renal vasoconstriction at high doses. Vasoconstriction was not produced by infusion of Tween alone. In addition, animals were treated with vehicle alone (Gp 1), CsA 10 mg/kg/day by injection (Gp 2), or CsA 20 mg/kg/day by i.v. infusion over 4 hr (Gp 3), and were studied at 1 week. Systemic toxicity was greater with the 4-hr infusion as judged by an increase in MAP. The mean values of MAP were 107 +/- 8 (Gp 1), 101 +/- 13 (Gp 2), and 135 +/- 5 mm Hg (Gp 3; p less than 0.05). However, renal function was less severely affected with the 4-hr infusion. The mean values of CIn were 434 +/- 99 (Gp 1), 298 +/- 101 (Gp 2; p less than 0.05), and 425 +/- 114 microL/min/100 g BW (Gp 3); and the mean values for RBF were 2.72 +/- 0.74 (Gp 1), 2.08 +/- 0.17 (Gp 2; p less than 0.05), and 3.35 +/- 0.61 mL/min/100 g BW (Gp 3), respectively. Microangiograms showed marked abnormalities in the intrarenal perfusion pattern in the rats injected with CsA, 10 mg/kg BW. In rats infused over 4 hr with CsA, 20 mg/kg BW, the microangiographic pattern was normal. These studies demonstrate that the acute hemodynamic effects of CsA are directly related to the rate of infusion. Furthermore, the renal toxicity which follows repetitive injection of CsA can be minimized or avoided by administering CsA as a slow infusion. In addition to the total dose administered, the rate of infusion is an important determinant of nephrotoxicity.     

Effect of cyclosporine administration on renal hemodynamics in conscious rats

The effect of acute and chronic administration of cyclosporine on systemic and renal hemodynamics was studied in conscious rats. Infusion of cyclosporine in a dose of 20 mg/kg (Cy 20) resulted in a significant fall in renal blood flow (RBF) (3.4 vs. 6.5 ml/min/g, P less than 0.05) and a rise in renal vascular resistance (RVR) (36.9 vs. 20.6 mm Hg/ml/min/g, P less than 0.05). Infusion of cyclosporine at a dose of 10 mg/kg (Cy 10) did not result in a significant change in RBF or RVR. Both doses of cyclosporine resulted in stimulation of plasma renin activity (PRA) from control values of 5.6 +/- 0.8 ng/ml/hr to 11.6 +/- 2.0 with 10 mg/kg and 26.7 +/- 5.6 with 20 mg/kg. Urinary 6-keto-PGF1 alpha excretion increased from control values of 14.0 +/- 2.0 ng/6 hr to 22.7 +/- 2.2 with 10 mg/kg and 25.0 +/- 2.0 with 20 mg/kg. Similar effects on RBF, RVR, PRA, and 6-keto-PGF1 alpha excretion were seen after chronic administration of cyclosporine (20 mg/kg i.p. for 7 days). Pretreatment of animals with captopril did not prevent the fall in RBF after cyclosporine, suggesting that the vasoconstriction was not mediated by angiotensin II. Animals treated with meclofenamate demonstrated reduction in RBF with 10 mg/kg cyclosporine (4.3 vs. 7.0 ml/min/g, P less than 0.05), suggesting that prostaglandins protect against the vasoconstrictor effect of cyclosporine. Administration of phenoxybenzamine after cyclosporine improved RBF (5.0 vs. 3.4 ml/min/g) and restored RVR to normal. Similarly, renal denervation dramatically reduced the fall in RBF after cyclosporine (innervated right kidney 3.6 vs. denervated left kidney 6.0 ml/min/g, P less than 0.001).(ABSTRACT TRUNCATED AT 250 WORDS)     

Hyperhomocysteinemia induces renal hemodynamic dysfunction: is nitric oxide involved?

Hyperhomocysteinemia is associated with endothelial dysfunction, although the underlying mechanism is unknown. Previous studies have shown that nitric oxide (NO) plays an important role in the regulation of systemic and renal hemodynamics. This study investigated whether hyperhomocysteinemia induces renal oxidative stress and promotes renal dysfunction involving disturbances of the NO-pathway in Wistar rats. During 8 wk, control (C) and hyperhomocysteinemic (HYC) groups had free access to tap water and homocysteine-thiolactone (HTL, 50 mg/kg per d), respectively. At 8 wk, plasma homocysteine concentration, renal superoxide anion (O(2)), nitrotyrosine, and nitrite+nitrate levels, and renal function were measured. To assess NO involvement, the responses to L-Arginine (L-Arg, 300 mg/kg) and N(G)-nitro-L-arginine-methyl-ester (L-NAME, 20 microg/kg per min for 60 min) were analyzed. The HYC group showed higher homocysteine concentration (7.6 +/- 1.7 versus 4.9 +/- 1.0 micromol/L; P < 0.001), (O(2) production (157.92 +/- 74.46 versus 91.17 +/- 29.03 cpm. 10(3)/mg protein), and nitrite+nitrate levels (33.4 +/- 5.1 versus 11.7 +/- 4.3 micro mol/mg protein; P < 0.001) than the control group. Western blot analyses showed a nitrotyrosine mass 46% higher in the HYC group than in the controls. Furthermore, the HYC group showed lower GFR, renal plasma flow (RPF), and higher renal vascular resistance (RVR) than the controls. After L-Arg administration, the responses of GFR, RPF, and RVR were attenuated by 36%, 40%, and 50%, respectively; after L-NAME, the responses of RPF and RVR were exaggerated by 79% and 112%, respectively. This suggests a reduced NO bioavailability to produce vasodilation and an enhanced sensitivity to NO inhibition. In conclusion, hyperhomocysteinemia induces oxidative stress, NO inactivation, and renal dysfunction involving disturbances on the NO-pathway.     

Aldosterone antagonism ameliorates proteinuria and nephrosclerosis independent of glomerular dynamics in L-NAME/SHR model

BACKGROUND: The renin-angiotensin-aldosterone system participates importantly in the progression of hypertensive renal disease. Angiotensin-converting enzyme inhibitors or angiotensin II receptor antagonists have been demonstrated to afford renoprotection in L-NAME-exacerbated nephrosclerosis in SHR rats. This study was designed to examine the effects of the aldosterone antagonist eplerenone on systemic and renal hemodynamics, glomerular dynamics, renal function and histopathology in L-NAME/SHR, and determine whether aldosterone antagonism would enhance the effectiveness of ACE inhibition. METHODS: Six groups of 20-week-old SHR were studied using renal micropuncture and histopathological techniques after 3 weeks of treatment: SHR control (tapwater, n = 10); SHR + eplerenone (101 +/- 8.3 mg/kg/day, n = 10); SHR + L-NAME (5.0 +/- 0.12 mg/kg/day, n = 9); SHR + L-NAME + eplerenone (n = 8); SHR + L-NAME + lisinopril (3 mg/kg/day, n = 9), and SHR + L-NAME + eplerenone + lisinopril (n = 9). RESULTS:L-NAME-treated SHR developed massive proteinuria, severe hypertensive nephrosclerosis, and tubulointerstitial damage. Eplerenone significantly reduced proteinuria (127.4 +/- 26.5 vs. 51.9 +/- 16.7 mg/24 h, p < 0.01), improved glomerular and arteriolar injuries (65 +/- 9 vs. 29 +/- 9 score/100 glomeruli, p < 0.01; 116 +/- 18 vs. 41 +/- 13 score/100 arterioles, p < 0.01, respectively), and decreased tubulointerstitial damage index (1.43 +/- 0.07 vs. 0.39 +/- 0.07, p < 0.01) without altering mean arterial pressure or glomerular dynamics. Combined therapy of eplerenone with lisinopril produced no further benefits than lisinopril alone. CONCLUSION: The aldosterone antagonist eplerenone significantly ameliorated proteinuria and nephrosclerosis in the L-NAME/SHR model, independent of hemodynamic effects.     

Relative roles of nitric oxide, prostanoids and angiotensin II in the regulation of canine glomerular hemodynamics. A micropuncture study

Glomerular hemodynamics are controlled by a variety of physical, nervous and hormonal factors including the potent vasoconstrictors, angiotensin (ANG) II and endothelin-1 (ET-1), and the vasodilator prostanoids (prostaglandin = PG) and nitric oxide (NO). Since no micropuncture data on the canine kidney exist with respect to the relative roles of the endogenous vasoactive hormones/autacoids NO, PG and ANG II in modulating glomerular hemodynamics, in the present study using the micropuncture technique in anesthetized dogs on a normal salt intake, we investigated the relative effects of these hormones/autacoids by means of the L-arginine analog, N(omega)-nitro-L-arginine methyl ester hydrochloride (L-NAME), a competitive NO synthase (NOS) inhibitor, the cyclooxygenase inhibitor indomethacin (INDO), and the AT(1) receptor blocker EXP 3174. An intrarenal arterial (i.r.a.) bolus (within 5 min) of 2.5 mg of L-NAME led to a significant decrease in total renal blood flow (RBF) and single nephron glomerular blood flow (SNGBF) from 4.46 +/- 0.51 to 3.52 +/- 0.41 ml/min/g kidney weight and from 0.393 +/- 0.041 to 0.341 +/- 0.037 microl/min (p < 0.01), respectively, without a change in glomerular filtration rate (GFR). The increase in arteriolar resistance was more pronounced at the efferent (+31%) than at the afferent (+13%) arteriole, and K(f) decreased from 4.5 +/- 0.5 to 3.7 +/- 0.4 nl/min/mm Hg (p < 0.01). INDO (5 mg/kg i.v. bolus followed by 0.17 mg/kg/min i.v.) had no effect on glomerular hemodynamics. EXP 3174 (30 microg/kg/min i.r.a.) increased RBF and SNGBF from 4.35 +/- 0.45 to 4.99 +/- 0.50 ml/min/g kidney weight and from 0.403 +/- 0.028 to 0.478 +/- 0.039 microl/min (p < 0.01), respectively, without an effect on GFR. It reduced the efferent arteriolar resistance by 25% as compared to 13% at the afferent arteriolar level. EXP 3174 increased K(f) from 5.1 +/- 0.4 to 8.1 +/- 0.6 mm Hg (p < 0.01) in the presence of a decrease in effective filtration pressure from 13.2 +/- 1.7 to 8.3 +/- 1.0 mm Hg (p < 0.01). The glomerular hemodynamic effects of L-NAME were unaltered by pretreatment with INDO or EXP 3174, whereas its tubular effects were restored in the presence of EXP 3174. Thus, from these first micropuncture data in the anesthetized dog on a normal sodium intake we conclude that (1) acute intrarenal inhibition of NOS by L-NAME decreases RBF and SNGBF due to vasoconstriction of the afferent and, more pronounced, efferent arterioles. Since L-NAME simultaneously decreases K(f), GFR remains unaltered. (2) These renal hemodynamic effects of NOS inhibition were not mediated by prostanoids or intrarenal ANG II. Thus, the tonic activity of intrarenal NOS plays an important role in maintaining glomerular hemodynamics in the canine kidney.     

Role of nitric oxide in the mechanism of preclamping and remote ischemic preconditioning of adipocutaneous flaps in a rat model

The purpose of this study was to determine whether nitric oxide (NO) plays a role in the mechanism of acute ischemic preconditioning (IP). Fifty-eight male Wistar rats were divided into seven experimental groups. An extended epigastric flap was raised in one of the control groups (C, n = 8), and a 3-hr flap ischemia was induced. Another group served as a non-ischemic control (CO, n = 8). The animals of group S (n = 9) received 500 nmol/kg of Spermine/Nitric Oxide Complex (Sper/NO) intravenously 30 min prior to ischemia. The group N+P (L-NAME + preclamping, n = 8) received 10 mg/kg Nomega-Nitro-L-Arginine Methyl Ester (L-NAME) intravenously before preclamping of the flap pedicle (10-min cycle length, 30-min reperfusion). Ten mg/kg L-NAME were administered in group N+T (L-NAME + tourniquet, n = 9) before ischemia of the right hindlimb was induced using a tourniquet for 10 min after flap elevation. Flap ischemia was induced after 30 min of limb reperfusion. A similar protocol was used in the groups N+P+S (L-NAME + preclamping+Sper/NO, n = 8) and N+T+S (L-NAME + tourniquet + Sper/NO, n = 8). In both groups Sper/NO was administered 30 min prior to flap ischemia, additionally to the protocol of the groups N+P and N+T. Mean flap necrosis area was assessed on the fifth postoperative day using a planimetry software. Average flap necrosis area was 67 +/- 16 percent in the control group C, 28 +/- 13.3 percent in the non-ischemic controls (CO), 10 +/- 5.9 percent in group S, 77.5 +/- 10.2 percent in group N+P, 76 +/- 6.9 percent in group N+T, 71.5 +/- 9.4 percent in group N+P+S, and 78 +/- 9.9 percent in group N+T+S. The animals of group S and CO demonstrated a significantly lower area of flap necrosis than all other groups ( p < 0.001). No significant difference could be shown between the groups C, N+P, N+T, N+P+S and N+T+S. Group S showed a significantly lower flap necrosis area than group CO ( p < 0.01). The data showed, that NO plays an important role in the mechanism of IP since the administration of an NO-donor previous to ischemia simulates the effect of IP, while the unspecific blocking of NO synthesis by L-NAME eliminates the protective effect of flap preconditioning by preclamping as well as by remote IP. Exogenous NO application is insufficient to provide protection once the endogenous NO synthesis is blocked.     

Nitric oxide in flow-through venous flaps and effects of L-arginine and nitro-L-arginine methyl ester (L-NAME) on nitric oxide and flap survival in rabbits

OBJECT: Venous flaps are relatively recent practices in plastic surgery, and their life mechanisms are not known exactly. Partial necroses frequently occur in these flaps; therefore, their survival should be enhanced. Nitric oxide (NO) is an endogenous compound which has recently been dwelt upon frequently in flap pathophysiology, and its effect on viability in conventional flaps has been demonstrated. However, its role in venous flaps is unknown. The purpose of this study is to determine possible changes in the NO level in venous flaps and to investigate the possible effects of NO synthesis precursor and inhibitor on the venous flap NO level and flap survival. MATERIAL AND METHODS: Thirty white male rabbits of New Zealand type, aged 6 months, were divided into 3 groups as control (n = 10), L-arginine (n = 10), and nitro-L-arginine methyl ester (L-NAME) (n = 10). Blood and tissue samples were taken from one ear of 10 rabbits in the control group for the determination of NO basal levels 2 weeks before flap practice. The 3-x-5-cm flow-through venous flaps, which are sitting on the anterior branch of the central vein, were elevated on each ear of 10 rabbits in all groups. After flaps were sutured to their beds, 2 mL/d saline, 1 g/kg/d L-arginine (NO synthesis precursor), and 50 mg/kg/d L-NAME (NO synthesis inhibitor) were administered intraperitoneally in control, L-arginine, and L-NAME groups, respectively, for 3 days. At the 24th postoperative hour, blood and tissue samples were taken from all animals for biochemical analyses. At day 7, flap survivals were assessed. RESULTS: Mean NO levels in the blood following the flap elevation (129 +/- 76 micromol/mg protein) increased in comparison with basal levels (59 +/- 44 micromol/mg protein) (P < 0.06); however, the tissue level remained unchanged. NO levels in the blood in the L-arginine and L-NAME groups were alike compared with the control group. The tissue NO level in L-NAME group (0.08 +/- 0.03 micromol/mg protein) decreased significantly compared to the control group (0.46 +/- 0.36 micromol/mg protein) (P < 0.001). Mean flap survival in the L-arginine group (95% +/- 6) increased according to the control group (61% +/- 14) (P < 0.001), whereas it did not change in the L-NAME group (55% +/- 13). CONCLUSION: In our model of venous flap, NO level in the blood increased, while it did not change in the tissue; L-arginine significantly enhanced flap viability without affecting NO level. Additionally, L-NAME decreased NO level, but it did not affect flap survival. In light of these findings, NO increases in venous flaps; the change in its level does not affect flap survival, though. However, L-arginine enhances venous flap survival if not by virtue of NO.     

Inhibition of nitric oxide synthase prevents hyporesponsiveness to inhaled nitric oxide in lungs from endotoxin-challenged rats.

BACKGROUND: Inhalation of nitric oxide (NO) selectively dilates the pulmonary circulation and improves arterial oxygenation in patients with adult respiratory distress syndrome (ARDS). In approximately 60% of patients with septic ARDS, minimal or no response to inhaled NO is observed. Because sepsis is associated with increased NO production by inducible NO synthase (NOS2), the authors investigated whether NOS inhibition alters NO responsiveness in rats exposed to gram-negative lipopolysaccharide (LPS). METHODS: Sprague-Dawley rats were treated with 0.4 mg/kg Escherichia coli O111:B4 LPS with or without dexamethasone (inhibits NOS2 gene expression; 5 mg/kg), L-NAME (a nonselective NOS inhibitor; 7 mg/kg), or aminoguanidine (selective NOS2 inhibitor; 30 mg/kg). Sixteen hours after LPS treatment, lungs were isolated-perfused; a thromboxane-analog U46619 was added to increase pulmonary artery pressure (PAP) by 5 mmHg, and the pulmonary vasodilator response to inhaled NO was measured. RESULTS: Ventilation with 0.4, 4, and 40 ppm NO decreased the PAP less than in lungs of LPS-treated rats (0.75+/-0.25, 1.25+/-0.25, 1.75+/-0.25 mmHg) than in lungs of control rats (3+/-0.5, 4.25+/-0.25, 4.5+/-0.25 mmHg; P < 0.01). Dexamethasone treatment preserved pulmonary vascular responsiveness to NO in LPS-treated rats (3.75+/-0.25, 4.5+/-0.25, 4.5+/-0.5 mmHg, respectively; P < 0.01 vs. LPS, alone). Responsiveness to NO in LPS-challenged rats was also preserved by treatment with L-NAME (3.0+/-1.0, 4.0+/-1.0, 4.0+/-0.75 mmHg, respectively; P < 0.05 vs. LPS, alone) or aminoguanidine (1.75+/-0.25, 2.25+/-0.5, 2.75+/-0.5 mmHg, respectively; P < 0.05 vs. LPS, alone). In control rats, treatment with dexamethasone, L-NAME, and aminoguanidine had no effect on inhaled NO responsiveness. CONCLUSION: These observations demonstrate that LPS-mediated increases in pulmonary NOS2 are involved in decreasing responsiveness to inhaled NO.     

Inhibition of Nitric Oxide Synthase Prevents Hyporesponsiveness to Inhaled Nitric Oxide in Lungs from Endotoxin-challenged Rats

Background: Inhalation of nitric oxide (NO) selectively dilates the pulmonary circulation and improves arterial oxygenation in patients with adult respiratory distress syndrome (ARDS). In approximately 60% of patients with septic ARDS, minimal or no response to inhaled NO is observed. Because sepsis is associated with increased NO production by inducible NO synthase (NOS2), the authors investigated whether NOS inhibition alters NO responsiveness in rats exposed to gram-negative lipopolysaccharide (LPS).

Methods: Sprague-Dawley rats were treated with 0.4 mg/kg Escherichia coli 0111:B4 LPS with or without dexamethasone (inhibits NOS2 gene expression; 5 mg/kg), L-NAME (a nonselective NOS inhibitor; 7 mg/kg), or aminoguanidine (selective NOS2 inhibitor; 30 mg/kg). Sixteen hours after LPS treatment, lungs were isolated-perfused; a thromboxane-analog U46619 was added to increase pulmonary artery pressure (PAP) by 5 mmHg, and the pulmonary vasodilator response to inhaled NO was measured.

Results: Ventilation with 0.4, 4, and 40 ppm NO decreased the PAP less than in lungs of LPS-treated rats (0.75 +/- 0.25, 1.25 +/- 0.25, 1.75 +/- 0.25 mmHg) than in lungs of control rats (3 +/- 0.5, 4.25 +/- 0.25, 4.5 +/- 0.25 mmHg; P < 0.01). Dexamethasone treatment preserved pulmonary vascular responsiveness to NO in LPS-treated rats (3.75 +/- 0.25, 4.5 +/- 0.25, 4.5 +/- 0.5 mmHg, respectively; P < 0.01 vs. LPS, alone). Responsiveness to NO in LPS-challenged rats was also preserved by treatment with L-NAME (3.0 +/- 1.0, 4.0 +/- 1.0, 4.0 +/- 0.75 mmHg, respectively; P < 0.05 vs. LPS, alone) or aminoguanidine (1.75 +/- 0.25, 2.25 +/- 0.5, 2.75 +/- 0.5 mmHg, respectively; P < 0.05 vs. LPS, alone). In control rats, treatment with dexamethasone, L-NAME, and aminoguanidine had no effect on inhaled NO responsiveness.     

The effects of cyclosporine on varying segments of small-bowel grafts in the rat

The relationship between the cyclosporine A (CSA) dose and rejection of varying lengths of small-bowel grafts was studied in a rat heterotopic microsurgical small-bowel transplantation model involving a haploidentical strain combination. When Lewis X Brown Norway F1 hybrid (LBN) small-bowel grafts were transplanted into Lewis (LEW) rats without CSA, all grafts in the proximal 10 cm, the proximal 40 cm, and the entire (approximately 80 cm) small bowel were rejected on days (mean +/- SEM) 6.6 +/- 0.2 (n = 11), 7.0 +/- 0.4 (n = 6), and 7.8 +/- 0.7 (n = 6), respectively. A 10-day course (days 0-9) of CSA 2 mg/kg significantly (p less than 0.05) prolonged the survival of the proximal 10 cm, the proximal 40 cm, and the entire small bowel allografts to days 18.8 +/- 1.7 (n = 5), 16.5 +2- 1.3 (n = 6), and 13.5 +/- 1.0 (n = 4), respectively. Similarly, the CSA 5 mg/kg regimen significantly (p less than 0.05) delayed the rejection of the 10 cm, the 40 cm, and the 80 cm small-bowel grafts to days 50.2 +/- 7.2 (n = 6), 47.7 +/- 2.6 (n = 3), and 40.3 +/- 5.8 (n = 3), respectively. However, 6 of 12 rats treated with CSA 5 mg/kg died of pneumonia, and these animals were all in groups with the 40 cm and 80 cm grafts. When these animals were included in calculations of rejection-free survival, the averages for the 40 and 80 cm groups treated with CSA 5 mg/kg were 34.2 +/- 6.4 and 28.7 +/- 6.1 days, respectively. CSA suppressed rejection of small-bowel allografts in a dose-related fashion. More important, significantly (p less than 0.05) lower doses of CSA were necessary for rats that received shorter intestinal grafts. In fact, the relationship between rejection and CSA dose in the 10 cm grafts was characterized by the formula: day of rejection = 9.3 [CSA dose]1.03. We conclude that the ideal small intestinal graft should be the smallest possible segment that maintains adequate nutrition and CSA doses should be matched for segment lengths.     

Effect of nitric oxide modulation on TGF-beta1 and matrix proteins in chronic cyclosporine nephrotoxicity

BACKGROUND: Chronic cyclosporine (CsA) nephrotoxicity is characterized by interstitial fibrosis and afferent arteriolar hyalinosis. L-arginine (L-Arg), the substrate for nitric oxide (NO) synthase and N-nitro-L-arginine-methyl ester (L-NAME), the NO synthase inhibitor, were shown to modulate acute CsA nephrotoxicity. However, the mechanism of fibrosis in chronic CsA nephrotoxicity remains unclear. Thus, we examined the effect of NO modulation on fibrosis and the expression of transforming growth factor-beta1 (TGF-beta1) and matrix proteins in chronic CsA nephrotoxicity. METHODS: Rats were administered CsA (7.5 mg/kg), CsA + L-Arg (1.7 g/kg), CsA + L-NAME (3.5 mg/kg), vehicle (VH), VH + L-Arg, and VH + L-NAME, and were sacrificed at 7 or 28 days. NO production, physiologic parameters, and histology were studied in addition to the mRNA expression of TGF-beta1, plasminogen activator inhibitor-1 (PAI-1) and the matrix proteins biglycan and collagens type I and IV by Northern and the protein expression of PAI-1 and fibronectin by enzyme-linked immunosorbent assay. RESULTS: While L-NAME strikingly reduced NO biosynthesis and worsened the glomerular filtration rate and CsA-induced fibrosis, L-Arg had the opposite beneficial effect. In addition, the CsA-induced up-regulated expression of TGF-beta1, PAI-1, and the matrix proteins biglycan, fibronectin, and collagen I was significantly increased with L-NAME and strikingly improved with L-Arg. Collagen IV expression was not affected. Also, NO modulation did not affect VH-treated rats. CONCLUSIONS: Chronic CsA nephrotoxicity can be aggravated by NO blockade and ameliorated by NO enhancement, suggesting that NO maintains a protective function. NO modulation was associated with a change in TGF-beta1 expression, which, in turn, was associated with alterations in matrix deposition and matrix degradation through its effect on PAI-1.     

EFFECTS OF NITRIC OXIDE SYNTHESIS INHIBITION ON FK506-INDUCED NEPHROTOXICITY IN RATS

This study was designed to evaluate the role of nitric oxide (NO) in FK506-induced nephrotoxicity by administering an inhibitor of NO synthesis, Nω-nitro-L-arginine methyl ester (L-NAME) to rats treated with FK506. After one week of treatment with FK506 (3.2 mg/kg/day, intramuscularly) and/or L-NAME (5 mg/100 mL of L-NAME in the drinking water), the arterial pressure, urinary NOx, and parameters for renal function were measured, and histological analysis of the kidney was made. In the L-NAME without FK506 group, L-NAME administration effectively inhibited urinary NOx excretion and increased mean arterial pressure (MAP) without any change in renal function. In the FK506 without L-NAME group, FK506 treatment showed increase in urinary NOx excretion and mild renal dysfunction. In the FK506 with L-NAME group, urinary NOx excretion was decreased by L-NAME administration and renal function was significantly worsened than FK506 without L-NAME group. The plasma creatinine, BUN and urinary N-acetyl-β-D-glucosaminidase increased 2-, 3-, and 3-fold, respectively and the creatinine clearance was reduced by 50% as compared with that in the FK506 without L-NAME group. Histological analysis revealed severe interstitial fibrosis and tubular atrophy in the FK506 + L-NAME treatment group. Thus, results suggest that NO synthesis is enhanced in the kidney during FK506-induced nephrotoxicity and that NO synthesis inhibition aggravates FK506-induced nephrotoxicity. NO may play a protective role attributable to the balance of vasoactive substances in FK506-induced nephrotoxicity.     

Effects of nitric oxide synthesis inhibition on FK506-induced nephrotoxicity in rats

This study was designed to evaluate the role of nitric oxide (NO) in FK506-induced nephrotoxicity by administering an inhibitor of NO synthesis, N omega-nitro-L-arginine methyl ester (L-NAME) to rats treated with FK506. After one week of treatment with FK506 (3.2 mg/kg/day, intramuscularly) and/or L-NAME (5 mg/100 mL of L-NAME in the drinking water), the arterial pressure, urinary NOx, and parameters for renal function were measured, and histological analysis of the kidney was made. In the L-NAME without FK506 group, L-NAME administration effectively inhibited urinary NOx excretion and increased mean arterial pressure (MAP) without any change in renal function. In the FK506 without L-NAME group, FK506 treatment showed increase in urinary NOx excretion and mild renal dysfunction. In the FK506 with L-NAME group, urinary NOx excretion was decreased by L-NAME administration and renal function was significantly worsened than FK506 without L-NAME group. The plasma creatinine, BUN and urinary N-acetyl-beta-D-glucosaminidase increased 2-, 3-, and 3-fold, respectively and the creatinine clearance was reduced by 50% as compared with that in the FK506 without L-NAME group. Histological analysis revealed severe interstitial fibrosis and tubular atrophy in the FK506 + L-NAME treatment group. Thus, results suggest that NO synthesis is enhanced in the kidney during FK506-induced nephrotoxicity and that NO synthesis inhibition aggravates FK506-induced nephrotoxicity. NO may play a protective role attributable to the balance of vasoactive substances in FK506-induced nephrotoxicity.     

Aluminum exacerbates cyclosporin induced nephrotoxicity in rats

Cyclosporin (CSA) has been universally used as an immunosuppressant for the management of allotransplantation and autoimmune diseases. However, nephrotoxicity of CSA limits its use to optimum level. Aluminum (Al) is an extensively distributed element in the environment and human exposure to this metal is unavoidable. Recent studies suggest that even a slight impairment of renal function may increase the Al body burden significantly, which may lead to neurotoxicity, nephrotoxicity, osteodystrophy or hypochromic anemia. In the present study, an attempt was made to study the effect of concomitant use of Al and CSA on structure and function of kidney in rats. This study was undertaken in two steps. In the first set of experiments, the effect of single dose of Al (1% Al2(SO4)3 18H2O) on the nephrotoxicity of multiple doses of CSA (12.5 mg/kg, 25 mg/kg and 50 mg/kg) was studied, where as in the second set of experiments the effect of multiple doses of Al (0.25%, 0.5% and 1%) on single dose of CSA (50 mg/kg) was undertaken. Male Sprague-Dawley rats (weighing 230 +/- 20 g) were used in this study. CSA was given once a day by gavage for seven days, where as Al was given in drinking water for the same period. Twenty four hours after the last dose of CSA, animals were sacrificed and blood and kidney were collected for biochemical and histopathological studies. The bio-chemical parameters included blood urea nitrogen (BUN), serum creatinine (SCr), CSA and Al levels. The kidney homogenates were assayed for malondialdehyde (MDA) and lipid hydroperoxides (LPH). Treatment of rats with CSA alone produced dose-dependent structural and functional changes in kidney. Although Al alone failed to produce any deleterious effect on renal function, it significantly increased the bioavailability and nephrotoxicity of CSA. Al also exacerbated CSA induced increase in oxidative stress (as evident by increased MDA and LPH). Thus, the exacerbation of CSA nephrotoxicity by Al may be attributed to increased bioavailability of CSA and excessive generation of free radicals following concomitant use of these drugs.     

Interaction of angiotensin II and nitric oxide in isolated perfused afferent arterioles of mice

The present study was performed to evaluate angiotensin II (Ang II)-nitric oxide (NO) interaction in afferent arterioles (Af) of wild-type mice and mice that are homozygous (-/-) for disruption of the endothelial NO synthase (eNOS) gene. Af were microperfused, and the dose responses were assessed for the NO precursor L-arginine (n = 4), NO inhibitor NG-nitro-L-arginine methyl ester (L-NAME, n = 5), L-NAME after pretreatment with L-arginine (n = 5), Ang II (n = 8), and Ang II after pretreatment with L-NAME (n = 7). Acute administration of L-arginine and L-NAME (both in doses from 10(-6) to 10(-3) mol/L) did not change arteriolar diameter. Moreover, pretreatment with L-arginine did not change the response to L-NAME. However, Ang II, applied in doses of 10(-12), 10(-10), 10(-8), and 10(-6) mol/L, significantly reduced the lumen to 66.5 +/- 7.0% and 62.2 +/- 8.0% at 10(-8) and 10(-6) mol/L Ang II, respectively. The contraction was augmented after L-NAME pretreatment (19.5 +/- 13.6% and 25.5 +/- 10.2% at 10(-8) and 10(-6) mol/L Ang II, respectively). In eNOS (-/-) mice (n = 8), the response to Ang II also was enhanced (9.1 +/- 6.0% and 11.2 +/- 8.2% at 10(-8) and 10(-6) mol/L Ang II, respectively). Female mice did not differ from male mice in their reactivity to Ang II (n = 9) and Ang II + L-NAME pretreatment (n = 11). The study shows that (1) it is feasible to microperfuse mouse Af, (2) the basal production of endothelial NO is very low and not inducible by L-arginine in Af of mice, and (3) a counteracting effect of NO is initiated by Ang II. High Ang II sensitivity in eNOS (-/-) mice underscores the considerable role of endothelial-derived NO to balance Ang II vasoconstriction in Af.     

Pharmacokinetics of Sirolimus and Tacrolimus in Pediatric Transplant Patients

To evaluate the pharmacokinetics of Sirolimus (SRL) and Tacrolimus (TAC) in pediatric transplant recipients. Fifty-one SRL and 55 TAC pharmacokinetic profiles were obtained from 20 male and 14 female recipients of liver alone (LTx, n = 23), small bowel alone, and with liver (SBTx, n = 11). The median age was 13.3 years (range 0.9-23.9). Whole blood concentrations of SRL and TAC were determined by liquid chromatography-mass spectrometry (LC-MS) and microparticulate enzyme immunoassay (MEIA-Abbott Laboratories, IL), respectively. Pharmacokinetic (PK) parameters were derived from noncompartmental model analysis. The half-life was estimated using the data points during the terminal disposition phase and area under the concentration (AUC) time curve was calculated within a dosing interval using the trapezoidal method. The dose of SRL or TAC did not correlate with the corresponding AUCs. Trough concentrations of SRL and TAC correlated well with AUC (r = 0.8544 and 0.8603, respectively). Half-life (h) did not differ significantly between different transplant groups for SRL and TAC (SRL: LTx: 21.2 h, SBTx: 19.3 h; TAC: LTx: 14.1 h, SBTx: 12.7 h). Serial PK analysis with the first measurement within 14 days after transplantation revealed no difference in AUC/dose/BSA for SRL, with time. During this period, SRL half-life increased significantly, from 11.2 +/- 1.0-20.1 +/- 3.1 h (n = 4; p = 0.02). After introduction of SRL, TAC half-life did not change (11.6 +/- 3.9-14.0 +/- 10.4, n = 10, P = 0.52) in all the groups analyzed together. TAC AUC/dose/BSA decreased significantly in LTx and SBTx patients (90.9 +/- 55.3 vs. 48.8 +/- 27.3). Trough concentration measurements provide good estimates of SRL and TAC exposure in pediatric transplant recipients. The short half-life of SRL in children may support twice-daily administration early after liver and small intestinal transplantation. During conversion of subjects from TAC to combined TAC and SRL, aggressive therapeutic drug monitoring must be used to individualize therapy and avoid serous adverse events.     

The role of nitric oxide synthase inhibition in the adverse effects of etomidate in the setting of focal cerebral ischemia in rats

We evaluated the effect of N(G)-nitro-L-arginine-methyl-ester (l-NAME, a nitric oxide synthase [NOS] inhibitor) and L-arginine (nitric oxide substrate) on cerebral mitochondrial dysfunction (hereafter referred to as "injury") after temporary middle cerebral artery occlusion (MCAo) during halothane or etomidate anesthesia in spontaneously hypertensive rats. Sixty minutes before MCAo, rats were randomized to 1 of 5 regimens (n = 8 per group): h/control, 1.2 minimum alveolar anesthetic concentration of halothane; h/L-NAME, 1.2 minimum alveolar anesthetic concentration of halothane and L-NAME (30 mg/kg); etomidate, an electroencephalographic (EEG) burst suppression dose of etomidate; e/L-NAME, an EEG burst suppression dose of etomidate and L-NAME (30 mg/kg); or e/L-NAME/arg, an EEG burst suppression dose of etomidate, L-NAME (30 mg/kg), and L-arginine (bolus of 300 mg/kg with an infusion at 35 mg x kg(-1) x min(-1)). After 180 min of MCAo and 120 min of reperfusion, volume of injury was determined using 2,3,5-triphenytetrazolium stain. Injury volume (mm(3), mean +/- sd) was larger in the etomidate group (153 +/- 17) than the halothane anesthetized h/control group (93 +/- 16) (P < 0.05) but did not differ between the e/L-NAME (162 +/- 17) and h/L-NAME groups (155 +/- 26). Injury volume in the e/L-NAME/arg group (88 +/- 15) was not different from the h/control group (93 +/- 16) and was less than that in either the etomidate or the e/L-NAME groups (P < 0.05). The data reproduce our previous observation that, relative to a halothane-anesthetized control state, etomidate has an adverse effect on ischemic injury in the setting of temporary focal cerebral ischemia. Prior inhibition of NOS with L-NAME resulted in no difference in the volume of injury between groups receiving etomidate or halothane (162 +/- 17 versus 155 +/- 26). Administration of a large dose of L-arginine prevented the adverse effect of etomidate. The data were obtained after only 2 h of reperfusion and therefore cannot be construed as representative of final neurologic outcome. They nonetheless suggest that etomidate produces an adverse effect on mitochondrial function early in the course of focal cerebral ischemia, in part, by inhibition of NOS.