Synthesis and anti-histaminic evaluation of N-phenyl-(alkyl)-5-(dialkylamino)methyl-2-amino-2-oxazolines.

New N-phenyl(alkyl)-5-(dialkylamino)methyl-2-amino-2-oxazolines, 5a-e, have been synthesized from the corresponding 3-phenyl(alkyl)carbamoyl-2-iminooxazolidines 2. A two-stage hydrolysis reaction led finally to the corresponding ring-opened N-phenyl(alkyl)-N'-[1-(3-(dialkylamino)-propan-2-ol)]ureas 4. The oxazoline ring was regenerated through an intramolecular nucleophilic substitution involving an halogen atom introduced by the reaction of thionyl chloride on 4. Pharmacological properties of 5a-e were evaluated on histaminic and adrenergic receptors in guinea-pig trachea and rat aorta. Compounds 5b and 5e showed a selective anti-histaminic effect on guinea-pig airways, but a significant response was obtained for a concentration >10(-6) M. No pharmacological activity was obtained with oxazoline 5c whereas oxazolines 5a and 5d seemed to present a non-selective effect on the contractile mechanism of the smooth muscle cell.

Smooth muscle cell changes during flow-related remodeling of rat mesenteric resistance arteries.

To obtain information on the molecular and cellular mechanisms of flow-induced arterial remodeling, we analyzed the morphology and smooth muscle cell (SMC) characteristics in rat mesenteric resistance arteries after interventions that decreased and increased flow. Juvenile male Wistar Kyoto rats were subjected to surgery that, compared with control arteries, provided arteries with chronic low flow and chronic high flow. Low flow resulted in a decreased passive lumen diameter, hypotrophy of the artery wall, and both loss and decreased size of SMCs. Time course studies, with intervention length ranging from 2 to 32 days of altered blood flow, showed that the narrowing of the lumen diameter in low-flow arteries appeared within 2 days and that an early dedifferentiation of SMC phenotype was indicated by markedly reduced levels of desmin mRNA. High flow resulted in an increased passive lumen diameter and in hypertrophy of the artery wall. The hypertrophy resulted from SMC proliferation because SMC number, measured by the 3D-dissector technique, was increased and immunohistochemical assessment of proliferating cell nuclear antigen also showed an increase. The widening of high-flow arteries required 16 days to become established, at which time desmin mRNA was reduced. This time was also required to establish changed wall mass in both low-flow and high-flow arteries. Apoptotic cells detected by TdT-mediated dUTP-biotin nick end labeling staining were mainly located in the medial layer, and evaluation of DNA fragmentation indicated that increased apoptosis occurred in both low flow and high flow. This study shows for the first time direct evidence that reduced and elevated blood flow in resistance arteries produce, respectively, decrease and increase in SMC number, with dedifferentiation of the SMCs in both cases.

Role of EDHF in the vasodilatory effect of loop diuretics in guinea-pig mesenteric resistance arteries.

1. Relaxing effect of loop diuretics, piretanide and furosemide in comparison with acetylcholine (ACh) was investigated in guinea-pig isolated mesenteric resistance arteries. 2. Concentration-response curves to ACh (0.001 - 10 microM) and diuretics (0.0001 - 1 microM) were constructed in noradrenaline (10 - 30 microM)-precontracted arteries incubated either in normal physiological salt solution (PSS) or in 30 mM KCl PSS (K-PSS). 3. In PSS, maximal relaxations (R(max)) and pD(2) to ACh were 87+/-2% and 7.1+/-0.1 (n=10). L-N(G)-nitro-arginine methyl ester (L-NAME, 100 microM) reduced R(max) by 20% (P<0.01, n=7) and pD(2) by 10% (P<0.01). In contrast, indomethacin (10 microM) increased R(max) by 19% (P<0.01, n=8) and pD(2) by 10% (P<0.05). Combination of L-NAME+indomethacin reversed the effect observed with either of these inhibitors used alone. In K-PSS, R(max) was attenuated by 40% (P<0.001, n=6) compared to PSS. L-NAME reduced R(max) by 65% (P<0.01, n=5) and increased pD(2) by 15 fold. L-NAME+indomethacin suppressed the resistant relaxation. 4. In PSS+L-NAME+indomethacin, inhibitors of small (SK(Ca); apamin, 0.1 microM) and large (BK(Ca); iberiotoxin and charybdotoxin, 0.1 microM) conductance Ca(2+)-sensitive K(-)-channels used alone had little effect on the ACh-response. Combination of apamin+iberiotoxin reduced R(max) by 40% (P<0.05, n=7) while apamin+charybdotoxin fully abolished the resistant relaxation. 5. In PSS, piretanide and furosemide induced relaxation with R(max): 89+/-3% vs 84+/-5% and pD(2): 8.5+/-0.1 vs 7.7+/-0.2 (P<0.01) for piretanide (n=11) and furosemide (n=10), respectively. Endothelial abrasion suppressed relaxation to diuretics. L-NAME and indomethacin used alone or in combination did not significantly modify the response to diuretics. 6. In K-PSS, piretanide-induced relaxation was abolished whereas that to furosemide was reduced by 70% (P<0.001, n=9) compared to PSS and was suppressed by L-NAME+indomethacin. In PSS+L-NAME+indomethacin, apamin slightly reduced relaxation to diuretics whereas charybdotoxin or iberiotoxin abolished the response. 7. These results indicate that ACh-evoked relaxation is mediated by both NO/PGl(2)-dependent and -independent mechanisms. The EDHF-dependent component relies on activation of Ca(2+)-activated K(+) channels, is sensitive to a combination of apamin+charybdotoxin and to a smaller degree to a combination of apamin+iberiotoxin. Loop diuretic-induced relaxation is endothelium-dependent, appears to be mediated by NO, PGl(2) and EDHF for furosemide and EDHF only for piretanide. For the two diuretics, opening of BK(Ca) channels may be involved in the relaxation.

Role of nitric oxide and endothelium in the flow-induced dilation of rat coronary arteries under two preconstriction conditions.

1. Pressure-induced tone and flow-induced dilations were studied in a rat perfused epicardial coronary artery mounted in an arteriograph. Spontaneous tone was assessed in arteries submitted either to 60 or 90 mmHg intraluminal pressure either under control conditions, after incubation with NG-nitro-L-arginine methyl ester (L-NAME; 100 mumol/L) or after endothelial denudation. Flow-induced dilation was quantified under these conditions in preparations either submitted to 60 mmHg and preconstricted with 10 mumol/L 5-hydroxytryptamine (5-HT) or exhibiting spontaneous tone at 90 mmHg. 2. Spontaneous tone was greater at 90 mmHg compared with tone obtained at 60 mmHg (21 +/- 2 vs 10 +/- 2% reduction of the fully dilated diameter after sodium nitroprusside incubation, respectively). Incubation with L-NAME or removal of the endothelium significantly increased spontaneous tone at both pressures compared with control. 3. In arteries submitted to 60 mmHg and preconstricted with 10 mumol/L 5-HT, flow (0-800 microL/min) induced a continuous dilation (maximal value 63 +/- 4%). As a function of flow, shear stress first increased and then plateaued at values of approximately 76 +/- 6 dyn/cm2. After L-NAME incubation or endothelial denudation, the flow-induced dilation was reduced to the same extent and was obtained for higher values of shear stress (172 +/- 14 and 150 +/- 14 dyn/cm2, respectively). 4. In arteries exhibiting spontaneous tone, starting flow led, first, to a constriction followed by a dilation up to 76 +/- 4% of the initial tone. Incubation with L-NAME greatly altered flow-induced dilation. Endothelium removal further reduced the dilation obtained for very high values of shear stress (up to 300 dyn/cm2). 5. The present study shows that different patterns of vasodilation induced by flow can be observed, depending on the initial vasoconstrictor stimulus. In 5-HT-preconstricted arteries, flow-induced dilation appears to be fully dependent on the synthesis and release of nitric oxide. In arteries with spontaneous tone, a vasoconstrictor substance could be released for low values of flow. Nitric oxide is mainly, but not exclusively, responsible for the vasodilation. For both experimental conditions, removal of the endothelium greatly reduced the response, but a dilation was still observed.

Trandolapril treatment at low dose improves mechanical and functional properties in perfused coronary arteries of spontaneously hypertensive rat.

The ex-vivo effects of a 1-month treatment period with trandolapril at a low dose (0.3 mg/kg/day) were assessed on the mechanical and functional alterations observed in SHR coronary arteries. The in-vitro intrinsic elastic properties of the wall in treated SHR coronary arteries were determined in comparison to those of SHR rats. In preconstricted preparations, agonist- and flow-induced dilatations were investigated in arteries of both groups. Arterial segments were cannulated at both ends using an arteriograph system. Internal diameter and wall thickness were continuously monitored while intraluminal pressure and flow were controlled. Wall thickness was reduced in arteries of treated rats compared to those in control SHR (mm): 52 +/- 2 vs. 41 +/- 2, P < 0.001, respectively. Arterial stiffness, expressed by the incremental elastic modulus-stress relationship, was significantly lower in arteries of treated compared to control SHRs. In preconstricted preparations, dilatations induced by bradykinin were significantly greater in treated SHR compared to control SHR arteries whereas dilatations induced by acetylcholine were slightly but not significantly increased. On the other hand, starting flow at the plateau of 5-HT-induced constriction led to dilatations which were not significantly different in the treated compared to the control group. The maximal dilatation induced by flow in arteries of treated rats was obtained for the same value of shear stress compared to that determined in preparations of control SHRs: (dyn/cm2) 63 +/- 3 vs. 61 +/- 2, respectively, NS. These results show that together with hypertrophy, the abnormal mechanical properties observed in the coronary arterial wall of SHR were improved by a low dose of trandolapril treatment. However, differential effects of trandolapril treatment were observed on agonist and flow-induced dilatations. Although flow-induced dilatation seemed to remain unaffected, acetylcholine-induced dilatation was slightly improved and bradykinin-induced dilatation was markedly increased by trandolapril treatment.

Vasomotor responses in chronically hyperperfused and hypoperfused rat mesenteric arteries.

We evaluated the reactivity of small arteries after remodeling induced by elevated or reduced blood flow. In 6-wk-old rats, every other first-order side branch of the superior mesenteric artery was ligated near the bifurcation of second-order branches. Four weeks after surgery, vessels that had been exposed to high flow (HF) or low flow (LF) were isolated and mounted in a pressure myograph at 100 mmHg and were compared with vessels from sham-operated rats (Sham). In HF: 1) basal lumen diameter was increased; 2) sensitivity to norepinephrine, arginine vasopressin, and perivascular nerve stimulation was not modified; 3) maximal constrictor responses (delta diameter) to these stimuli and 125 mM K+ were increased; and 4) sensitivity and maximal dilator responses to sodium nitroprusside, acetylcholine, and flow were not modified. In LF: 1) basal diameter was reduced; 2) sensitivity to constrictor stimuli was not altered; 3) maximal responses to all vasoconstrictors except arginine vasopressin were reduced; and 4) sensitivity but not maximal dilator responses to sodium nitroprusside and acetylcholine was reduced. During acute flow-induced dilatations, lower shear stress was maintained in HF (48 +/- 7 dyn/cm2) than in Sham (63 +/- 10 dyn/cm2), but no shear stress regulation was observed in LF. These observations indicate that arterial structural responses to altered blood flow are accompanied by modified reactivity of the arterial smooth muscle, which entails changes in responsiveness to neurogenic and endothelium-dependent stimuli.

The elastic modulus of conductance coronary arteries from spontaneously hypertensive rats is increased.

OBJECTIVE: To assess the alterations of morphological and functional properties of conductance coronary and mesenteric resistance arteries in spontaneously hypertensive rats (SHR). DESIGN: The in-vitro intrinsic elastic properties of the wall material in SHR coronary arteries were determined in comparison with those of Wistar-Kyoto (WKY) rats. Mesenteric resistance arteries from rats of both strains were also studied. METHODS: Arterial segments were cannulated at both ends using an arteriograph system and subjected to pressure increments with simultaneous measurements of the wall thickness and internal diameter. The strain, stress and incremental elastic modulus (Einc) were calculated from diameter-pressure curves. RESULTS: Over the full range of pressures tested (10-160 mmHg), the internal diameters of SHR coronary arteries were not significantly different from those of WKY rat arteries, whereas we observed that SHR mesenteric resistance arteries had a significantly smaller diameter. The stress-strain curve for coronary arteries was shifted significantly to the left-hand side for the SHR group indicating more stress per unit strain, whereas the opposite was found for mesenteric resistance arteries. When Einc was determined under isobaric conditions, we found no difference between SHR and WKY rat coronary arteries, whereas this parameter was decreased significantly for SHR mesenteric resistance arteries. When Einc was estimated at the respective operating pressures, it was 1.7- to 2.8-fold greater for SHR than it was for WKY rat mesenteric resistance and coronary arteries. Moreover, the total collagen area: lumen area ratio was significantly greater for the SHR than it was for the WKY rat coronary artery wall, but this ratio was similar for mesenteric preparations from the two strains. CONCLUSION: These results show that, at a given stress or operating pressure level, the material of SHR coronary artery wall is characterized by an increase in Einc, whereas there is no increase in Einc for in mesenteric resistance arteries. This functional alteration is accompanied by an increase in the relative proportion of collagen, a component with a high elastic modulus, in the wall. In contrast, we found no change in elastic modulus and in the relative proportion of collagen for the SHR mesenteric resistance arteries. Furthermore, the present results support the hypothesis that alterations in distensibility differ among the components of the SHR vasculature.

Structural properties of rat mesenteric small arteries after 4-wk exposure to elevated or reduced blood flow.

We determined the structure of mesenteric small arteries after chronic elevation and chronic reduction of blood flow. In 6-wk-old rats, we ligated second-order side branches of every other first-order side branch of the superior mesenteric artery. This persistently reduced blood flow (-90%) in the vessels feeding into the ligated trees and elevated blood flow (+80%) in the nonligated mesenteric artery side branches. Four weeks after surgery, vessels that had been exposed to high blood flow (HF) or low blood flow (LF) and vessels from sham-operated rats (Sham) were isolated and mounted in a pressure myograph system. At an intraluminal pressure of 100 mmHg, the internal diameter at rest was larger in HF (533 +/- 23 microm) and smaller in LF (262 +/- 14 microm) than in Sham vessels (427 +/- 15 microm). Also, wall and media cross-sectional areas were larger in HF and smaller in LF than in Sham vessels (media: 22 +/- 1, 11 +/- 2, and 16 +/- 1 x 10(3) microm2, respectively), but circumferential wall stress did not differ among groups. DNA content was significantly increased in HF vessels (+100%) and was not modified in LF vessels. Maximal vasoconstrictions elicited by high potassium or norepinephrine were slightly increased in HF vessels but were reduced by 50% in LF vessels. Thus chronic changes in blood flow give rise to structural changes that normalize circumferential wall stress. Elevated blood flow resulted in outward hypertrophic remodeling involving hyperplasia. Reduced blood flow resulted in inward hypotrophic remodeling accompanied by hyporeactivity of the arterial smooth muscle.

Effects of nitric oxide and sodium nitroprusside on the intrinsic elastic properties of pressurized rat coronary artery.

The study was designed to assess the influence of either nitric oxide (NO) or sodium nitroprusside and the absence of endothelium on the intrinsic elastic properties of coronary arteries from WKY rats. For this purpose, segments of the right interventricular coronary were mounted in an arteriograph where wall thickness and internal diameter were continuously monitored while intraluminal pressure was controlled in the absence of flow. To study the passive properties, pressure-diameter relationships were determined by measuring the corresponding internal diameter for each stepwise increase in intraluminal pressure. Thus, wall stress, strain and incremental elastic modulus (Einc) were assessed in the following experimental conditions: control, incubation with nitro-L-arginine methyl ester (L-NAME, 100 microM) or L-NAME + L-arginine (L-arg, 100 microM), incubation with sodium nitroprusside (SNP, 100 microM), endothelium removal (CHAPS). The Einc-stress relationship was not significantly different in the different experimental conditions, but values of Einc plotted as function of strain were significantly decreased after L-NAME incubation and partly reversed after L-arg addition. The same effect was observed after endothelium destruction but to a lesser extent. After SNP incubation, values of Einc were significantly decreased for small values of strain and increased for high values of this parameter. These results show that NO synthase inhibition induced, for a given strain, a decrease of elastic modulus in coronary arteries. It can be speculated that functional antagonism exerted by NO against spontaneous contractile tone was reduced. Thus, the smooth muscle cells were in a greater state of activation and probably more strongly involved in the intrinsic elastic properties of this preparation. However, an unexplained effect of NO on wall stiffness cannot be excluded. Conversely, SNP increased the initial diameter and induced an initial decrease in stiffness followed by a subsequent increase. After endothelium destruction, stiffness was significantly decreased compared to control conditions. It can be concluded that NO modulates the intrinsic elastic properties of the coronary arteries through smooth muscle cell relaxation. Furthermore, results with SNP support the hypothesis that the lower the state of activation of the smooth muscle cells, the higher the elastic modulus of the arterial wall in this coronary artery preparation.

[Effects of short-term treatment with trandolapril on vasodilatator responses mediated by receptors or on blood flow in the coronary arteries in SHR]. / Effets d'un traitement court par le trandolapril sur les réponses vasodilatatrices médiées par des récepteurs ou le débit au niveau d'artères coronaires chez le SHR.

The aim of the study was to assess the effects of a one-month treatment period with the ACE inhibitor trandolapril (0.3 mg/kg/day) on the endothelial reactivity in epicardial right coronary arteries (CA) of 26-30 week-old SHRs. For this purpose, segments of CA were mounted in an arteriograph where wall thickness and internal diameter (ID) were continuously monitored while intraluminal pressure (IP) was controlled. In the absence of flow and under an IP of 30 mmHg, IDs were not significantly different in control compared to those of treated SHR arteries (microns, 250 +/- 8 vs 240 +/- 7). In preconstricted preparations (5HT, 10 microns extraluminally) C/E curves were constructed by adding acetylcholine (AC, 0.01-10 microM) or bradykinin (BK, 0.01-10 microM) in the bath. On the other hand, the effect of a stepwise increase in intraluminal flow (50-450 microliters/min; IP = 30 mmHg) of perfusion solution was observed. The effects of subsequent additions of sodium nitroprusside (SNP) were assessed. Maximal relaxations were expressed as percent of maximal contractions. Results were as follows: [table: see text] These results show that the endothelium-dependent relaxation induced by AC and BK were significantly increased in coronary arteries of treated compared to control SHRs whereas the flow-induced relaxation seemed to remain unaffected in our experimental conditions. From these data, it can be concluded that a short period of ACE inhibition in SHRs is able to improve the endothelium-dependent vasodilation induced by agonists in the coronary arterial bed.

Impaired endothelial relaxations induced by agonists and flow in spontaneously hypertensive rat compared to Wistar-Kyoto rat perfused coronary arteries.

The study was designed to compare the effects of agonists and flow on endothelial reactivity in perfused coronary arteries of spontaneously hypertensive rats (SHRs) and Wistar-Kyoto (WKY) rats. To this end, coronary arteries were cannulated at both ends using an arteriograph system. In the absence of flow and under an intraluminal pressure of 30 mm Hg, SHR arteries had larger internal diameters compared to those of WKY rats (275 +/- 10 vs. 239 +/- 7 microns, p < 0.01). In preparations preconstricted with serotonin HT, concentration-effect curves were constructed by adding acetylcholine or bradykinin in the bath. On the other hand, the effect of a stepwise increase in intraluminal flow (50-450 microliters/min) of physiological salt solution was observed. Agonist-induced dilations were significantly smaller in arteries of SHRs compared to those of WKY rats. Starting flow at the plateau of constriction led to dilations that were also weaker in SHR compared to WKY vessels: 27 +/- 6 vs. 61 +/- 3, p < 0.001, when expressed as percentage of maximal initial constrictions. The maximal dilation induced by flow in SHR arteries was obtained for a greater value of shear stress compared to that determined in WKY preparations: 81 +/- 6 vs. 60 +/- 4 dyn/cm2, p < 0.01. After endothelium destruction, flow-induced dilation was totally abolished in SHR arteries but only reduced in those of WKY rats. Subsequent additions of sodium nitroprusside induced complete dilations in vessels from both strains. The same protocol was performed in arteries submitted to a perfusion pressure of 90 mm Hg. In these conditions, impairments of agonist- and flow-induced dilations were also evidenced in SHR arteries. These results show that both the endothelium-dependent dilation induced by acetylcholine or bradykinin and the flow-induced dilation are impaired in coronary arteries of SHRs compared to WKY rats. These alterations appear to be due to a deterioration of endothelial cell function in the presence of a normal reactivity of the smooth muscle cells.

Endothelial and smooth muscle properties of coronary and mesenteric resistance arteries in spontaneously hypertensive rats compared to WKY rats.

To investigate if the functional alterations observed in resistance arteries of spontaneously hypertensive rats (SHRs) were also present at the coronary level, in vitro experiments were performed in mesenteric resistance arteries (MRA) and in right (RIC) and left interventricular coronary (LIC) arteries taken from 15-25-week-old SHR and age-matched Wistar Kyoto rats WKYs. Using a passive extension protocol, internal diameters corresponding to 100 mmHg intraluminal pressure (D100) were determined and vessels were set up to a normalized internal diameter (0.9 D100). SHR mesenteric resistance arteries had a significantly smaller diameter compared to WKY arteries, whereas both types of SHR coronary arteries had a greater diameter compared to those of WKY rats. In arteries in the absence of contracting agonist, nitro-L-arginine (NOLA, 100 microM) induced a progressive rise in basal tone, which could be reversed by subsequent addition of L-arginine (100 microM) but not D-arginine (100 microM). When expressed as percent of maximal contractions induced by agonists (noradrenaline, NA [10 microM] in MRA; serotonin, 5-HT [10 microM], in RIC and LIC), these contractions were significantly stronger in WKY compared to SHR coronary and mesenteric resistance arteries. In NA-precontracted MRA and 5HT-precontracted coronary arteries in the presence of indomethacin (10 microM), the magnitude of acetylcholine-induced maximal relaxations (expressed as percent of maximal contractions induced by agonists) was greater in WKY compared to SHR arteries. After a 30-min incubation period, NOLA (100 microM) completely inhibited relaxations induced by acetylcholine (0.01-10 microM) in all types of precontracted arteries.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of trandolapril on vascular morphology and function during the established phase of systemic hypertension in the spontaneously hypertensive rat.

The aim of this study was to determine the morphologic and functional vascular changes occurring following 4 weeks of treatment with the angiotensin-converting enzyme inhibitor trandolapril in the spontaneously hypertensive rat (SHR) in the established phase of hypertension. At the dosage used, 0.4 mg/kg orally, trandolapril decreased blood pressure of the SHR by 15-18% compared with that of the control animals. Immediately before the end of treatment, the following changes from control values were observed: (1) 9, 11, and 12% reductions for myocardial hypertrophy and the media thickness of the thoracic aorta and femoral arteries, respectively; and (2) an increase in the compliance of the resistance arteries, demonstrated by a shift to the right of the in vitro tension-diameter curves and a significant 22% increase in their normalized internal diameter, while their maximum contractile ability was significantly decreased. Following discontinuation of treatment, blood pressure levels remained significantly lower in the treated versus the control groups for up to 4 weeks after the last administration. At that time measurement of the studied parameters showed: (1) a rapid reversion to control values of the compliance of the resistance vessels; and (2) a slower progression, but in the same direction, in the parameters of cardiac and vascular hypertrophy. Thus, trandolapril, administered for a short period in the adult SHR, was able to reverse the cardiac and vascular morphologic changes present in this model of hypertension. Like the effect on blood pressure, these effects were slowly reversible at the end of treatment, whereas the functional consequences at the resistance artery level seemed to display a more rapid reversibility.