Development and characterization of rat monoclonal antibodies to denatured mouse angiotensin-converting enzyme.

Four new rat monoclonal antibodies, generated to denatured mouse somatic angiotensin-converting enzyme (ACE, CD143), detect mouse ACE with high sensitivity in Western blotting. Epitope mapping for the monoclonal antibodies--B12, 4G6 and 5C4--was also performed. Two monoclonal antibodies--B12 and 5C4--are directed to various epitopes on the N-domain--i.e., they recognized only the somatic isoform of mouse ACE. The monoclonal antibody H7 recognized an epitope on the C-domain of mouse ACE. The monoclonal antibody 4G6 was directed to a sequence on the N-domain of mouse ACE, which is homologous to a region of the C-domain and, as a result, also recognizes mouse testicular ACE (tACE) by means of Western blotting. In paraffin-embedded mouse tissues, all monoclonal antibodies detected all known expression sites of somatic ACE (sACE), e.g., the epithelial cells of the kidney proximal tubules, intestine and epididymis, and heterogeneously in endothelial cells. The monoclonal antibodies 4G6 and H7 additionally stained mouse tACE in spermatozoa and in mature spermatids. The monoclonal antibody 4G6 also demonstrated cross-reactivity with sACE from a broad spectrum of animal species, including human, rat, rabbit and bovine. However, this monoclonal antibody did not recognize the testicular isoform of ACE of these species. This set of monoclonal antibodies is useful for identifying even subtle changes in mouse ACE conformation because of denaturation. These monoclonal antibodies are also sensitive tools for the detection of mouse ACE in biological fluids and tissues by using proteomics approaches. Their high reactivity in paraffin-embedded tissues opens up opportunities to study possible changes in the pattern of ACE expression in knockout mouse models and may prove useful for correlating ACE expression in these models with human diseases.

Glyburide decreases myocardial oxygen pressure in dogs.

BACKGROUND: Reports show that glyburide, an adenosine triphosphate sensitive potassium (K+ATP) channel blocker, will reverse the myocardial protective effect of inhalational anesthesia. We evaluated the effect of glyburide on myocardial tissue oxygen pressure (PmO2) in dogs anesthetized with desflurane. METHODS: Twelve dogs were anesthetized with 8% end-tidal desflurane for baseline anesthesia. A flow probe was placed on the left anterior descending (LAD) artery. A probe that measured PmO2 was inserted into the middle myocardium in the LAD region. After baseline measures, six dogs received i.v. 1 mg kg(-1) of glyburide and six dogs received sham vehicle treatment. After the glyburide or sham treatment, each dog received an i.v. infusion of adenosine 0.1 microg kg(-1) x min(-1), sodium nitroprusside (SNP) 2-4 microg kg(-1) x min(-1) and 14% end-tidal desflurane in random order. RESULTS: Glyburide decreased LAD artery flow from 59 +/- 9 ml min(-1) to 30 +/- 6 ml min(-1) (P < 0.05) and PmO2 from 44 +/- 16 mmHg to 30 +/- 9 mmHg (P < 0.05). Adenosine infusion increased LAD artery blood flow 180% in the sham-treated dogs but produced no change in the glyburide-treated dogs. Sodium nitroprusside infusion increased LAD artery flow and decreased PmO2 in both the glyburide- and sham-treated dogs. Desflurane (14%) did not reverse the glyburide-induced vasoconstriction but increased PmO2 to 38 +/- 20 mmHg (P < 0.05). CONCLUSION: Glyburide produced myocardial tissue hypoxia, which was not changed by adenosine, worsened by SNP and improved by 14% desflurane. The improvement in PmO2 with desflurane occurred without a change in myocardial blood flow.

Myocardial tissue oxygen during coronary artery constriction and hypotension in dogs.

BACKGROUND: Sodium nitroprusside (SNP) may decrease myocardial tissue oxygenation in dogs with normal coronary arteries. We compared SNP- with desflurane-induced hypotension on myocardial tissue oxygen and pH in dogs with left anterior descending artery constriction. METHODS: Twenty-four dogs were anesthetized with 8% desflurane for baseline anesthesia. Catheters were inserted into the femoral artery and vein and the coronary sinus. A flow probe and flow restriction device was placed on the left anterior descending (LAD) artery. A probe that measured myocardial oxygen pressure was inserted into the middle myocardium in the LAD region. Baseline measures were made of LAD artery flow, arterial and coronary sinus blood gases, and myocardial tissue gases. A 30% decrease in blood pressure was induced with SNP with unrestricted LAD flow (n=6) or when LAD artery flow was restricted by 30% from baseline (n=6). In separate dogs, a 30% decrease in blood pressure was produced with 14 +/- 1% desflurane with unrestricted LAD flow (n=6) or with baseline LAD artery flow restricted by 30% (n=6). RESULTS: During SNP-induced hypotension with no LAD constriction, LAD artery flow and coronary sinus oxygen tension increased but myocardial tissue oxygen tension (PmO2) decreased by 40%. When baseline artery flow was decreased by 30% by LAD constriction, SNP-induced hypotension decreased tissue oxygen pressure by 80%, and ischemic acidosis was produced. During unrestricted LAD artery flow or with a 30% flow restriction, desflurane-induced hypotension produced no significant change from baseline myocardial tissue oxygen tension or pH. CONCLUSION: During coronary artery constriction, desflurane-induced hypotension maintained myocardial tissue oxygenation and pH better than did SNP-induced hypotension. The divergence between tissue and coronary sinus oxygen tension during SNP suggests that arteriovenous shunting may occur.

Brain compared to heart tissue oxygen pressure during changes in arterial carbon dioxide in the dog.

Myocardial tissue oxygen pressure (PmO2 ) and left anterior descending (LAD) artery blood flow were measured in dogs anesthetized with 1.5% isoflurane, and were then compared to brain tissue oxygen pressure (PbO2 ) and middle cerebral artery (MCA) blood flow during normocapnia, hypocapnia, and hypercapnia. A craniotomy was performed and a tissue probe (Codman, Inc.) that measures PO2, PCO2, and pH was inserted into the brain cortex in the MCA region (n = 8). Separately, after a thoracotomy, a probe was inserted into the middle myocardium of the left ventricle, within the distribution of the LAD, in eight dogs. Blood flow probes were placed on the LAD or MCA. Blood flow and tissue gases were measured during normocapnia (PaCO2 = 38 mm Hg), hypocapnia (PaCO2 = 26 mm Hg), and hypercapnia (PaCO2 = 53 mm Hg). Mean arterial pressure, heart rate, arterial gases, and pH were not different between brain and heart measurements. PbO2 was 21 +/- 9 mm Hg (mean +/- SD ), 40 +/- 16 mm Hg, and 47 +/- 11 mm Hg. PmO2 was 35 +/- 12 mm Hg, 40 +/- 14 mm Hg, and 48 +/- 15 mm Hg during hypocapnia, normocapnia, and hypercapnia respectively. During hypercapnia, LAD and MCA flow increased 50% and tissue oxygenation increased 20% ( P < .05). During hypocapnia, MCA flow and PbO2 decreased 50% ( P < .05), but LAD flow and PmO2 did not significantly change. These results indicated that LAD flow and myocardial PO2 were less responsive to hypocapnia than MCA flow and PbO2.

Occurrence of potentially detrimental temperature alterations in hospitalized patients at risk for brain injury.

OBJECTIVE: To ascertain the incidence and timing of fever in patients at risk for temperature modulation of brain injury resulting from ischemia or trauma. DESIGN: We retrospectively reviewed the medical records of patients admitted between January 1991 and December 1994. MATERIAL AND METHODS: We investigated three groups of hospitalized patients considered at risk for ongoing brain injury resulting from a prior cerebral insult: successful resuscitation from out-of-hospital cardiac arrest (CA), subarachnoid hemorrhage (SAH), or traumatic closed-head injury (CHI). Forty patients per condition were randomly selected from those who survived for more than 24 hours after hospital admission. RESULTS: During the initial 72 hours of hospitalization, temperature increases to 38 degrees C or more (that is, temperatures previously reported to worsen neurologic outcome after brain injury) were noted in 83% of patients with CA, 70% of those with SAH, and 68% of those with CHI. Within the cohort of febrile patients, 18 to 44% of all temperature measurements were 38 degrees C or higher, and the febrile episodes occurred randomly throughout the study interval. Fewer than one-eighth of the febrile patients received drugs possessing antipyretic properties (such as aspirin or acetaminophen) in a dose appropriate to treat fever. No other method of temperature control (for example, physical means) was used in any patient. The fractions of patients who were dismissed from the hospital with permanent neurologic injury were as follows: CA, 20%; SAH, 45%; and CHI, 43%. CONCLUSION: In these hospitalized patients at risk for ongoing brain injury, the incidence of temperature increases within the range reported to worsen neurologic outcome (elevations of 1.0 degree C or more) was very high. The characterization of these potentially injurious, randomly occurring, and traditionally undertreated temperature increases may have implications for the design of future protocols aimed at providing cerebral protection.

The influence of chronic hypokalemia on myocardial adrenergic receptor densities: enhanced sensitivity to epinephrine-induced arrhythmias.

We studied the effects of a 30-day potassium (K+)-deficient diet on blood [K+] myocardial adrenergic receptor densities, serum catecholamines, and epinephrine arrhythmogenicity in adult laboratory rats (250 +/- 25 g). Within 3 days of beginning the K+-deficient diet, blood [K+] decreased by 50%. After 5 days, the myocardial alpha-1 density increased (62 +/- 2 vs 148 +/- 16 fmols/mg protein), and the total beta receptor increased (95 +/- 5 vs 273 +/- 49) without significant change in receptor affinity. However, 18-21 days of this diet was necessary to produce an increase in the duration of epinephrine arrhythmias (from 56 +/- 8 to 224 +/- 21 s). While prazosin block of the alpha-1 receptor in hypokalemic rats caused a significant, 42% reduction in arrhythmic duration and propranolol block caused a 62% reduction, both prazosin and propranolol were necessary to return arrhythmia times to normal (44 +/- 0.3 mmols/dL). Total serum catecholamines were reduced after 3 days of the diet (from 482 +/- 37 to 299 +/- 31 pg/ml) and remained depressed throughout the 30 days of the K+ diet. The results of this study indicate that prolonged restriction causes a reduction in serum catecholamines, an increase in myocardial alpha-1 and beta receptors densities, and an increase in epinephrine arrhythmogenicity. All of these changes were reversed within 5 days of initiating a normal dietary K+ intake.

Divergence of intracranial and central venous pressures in lightly anesthetized, tracheally intubated dogs that move in response to a noxious stimulus.

BACKGROUND: Intracranial pressure (ICP) may increase in tracheally intubated subjects during periods of movement (e.g, "bucking" and coughing). Recent research has suggested that factors other than passive congestion of the cerebral vessels, resulting from increases in central venous pressure, may contribute to the ICP response. The current study evaluated this issue in a canine model of intracranial hypertension and additionally evaluated the relationship between ICP and static increases in superior vena caval pressure. METHODS: Six dogs were lightly anesthetized with 0.65% end-expired halothane in oxygen and nitrogen, and ventilation was mechanically controlled. Intracranial pressure was increased to a stable baseline of 15-20 mmHg using a subarachnoid infusion of warm 0.9% saline solution. The following variables were quantified before, and for 6 min after, initiating a 1-min noxious stimulus to the trachea and skin: ICP, central venous pressure, electromyograms (masseter, deltoid, and intercostal muscles), intrathoracic pressure, and cerebral perfusion pressure (defined as mean arterial pressure -- ICP). Later, the protocol was repeated in the presence of neuromuscular block with pancuronium. Finally, in the same dogs, occlusion of the superior vena cava at its junction with the right atrium was used to increase superior vena caval pressure in 5-mmHg increments, from 5 to 30 mmHG, so that the resulting increases in ICP could be quantified. RESULTS: In unparalyzed dogs whose heads were maintained at the level of the right atrium, there was a 22-mmHg increase in ICP at 1 min after initiating the noxious stimulus (P<0.05). The ICP increase was related to electromyogram activation and a 6-mmHg increase in central venous pressure; however, it was not associated with significant increases in intrathoracic pressure or cerebral perfusion pressure. Treatment with pancuronium abolished the electromyographic, ICP, and central venous pressure responses to noxious stimulus. When superior vena caval pressure was statically manipulated, the resulting ICP increase was only one half the magnitude of the superior vena caval pressure increase. After elevating the head 14 cm, the ratio of ICP to superior vena pressure increases was reduced to one third. CONCLUSIONS: If these results apply to humans, it was concluded that increases in ICP that accompany movement in tracheally intubated patients may arise from two complementary factors: (1) cerebrovascular dilation that correlates with electromyographic activity and is mediated by ascending neural pathways that transmit proprioreceptive information, and (2) passive venous congestion that results from any increase in central venous pressure. The influence of the latter factor can be reduced by elevating the head. (Key words: Blood pressure, venous pressure; mean arterial pressure. Muscle: afferent activity; electromyograms, skeletal. Neuromuscular relaxants: pancuronium.)

The bispectral index during induction of anesthesia with midazolam and propofol.

This study evaluated the bispectral index as an indicator of anesthetic depth in relation to the cardiovascular response to intubation. Two treatments were compared: group 1 (n = 8) received propofol for induction of anesthesia (2 mg/kg bolus followed by an infusion of 0.20 mg/kg-1/min-1, group 2 (n = 8) was given 90 micrograms/kg midazolam 2 min before, followed by anesthesia with half-strength propofol (1 mg/kg bolus with infusion of 0.10 mg/kg-1/min-1). The bispectral index of the electroencephalogram, blood pressure, and heart rate were measured under unanesthetized conditions, during anesthetic induction, intubation, and a 15-min period after intubation. The duration of anesthesia and the total propofol requirement were recorded. Midazolam pretreatment produced transient decreases in blood pressure and the bispectral index. During anesthetic induction with propofol, blood pressure decreased 20% in both groups, and the bispectral index decreased to lower levels in group 1 (29 +/- 9) than in group 2 (47 +/- 22). Intubation increased blood pressure more in group 2 (50 +/- 10 mm Hg) than in group 1 (30 +/- 12 mm Hg). Throughout the rest of the surgery, more propofol was used in group 1 (77 +/- 14 micrograms/kg-1/min-1) than in group 2 (42 +/- 14 micrograms/kg-1/min-1). These results show that the decrease in bispectral index provides an indication of the blood pressure increase to intubation during propofol anesthesia. Midazolam pretreatment did not attenuate the cardiovascular response to intubation but did decrease propofol use during surgery.

Role of nitric oxide, adenosine, N-methyl-D-aspartate receptors, and neuronal activation in hypoxia-induced pial arteriolar dilation in rats.

In this study, we tested the hypothesis that nitric oxide (NO) and adenosine (ADO) are the principal mediators of severe hypoxia-induced vasodilation. In addition, we examined whether activation of N-methyl-D-aspartate (NMDA) receptors and/or perivascular nerves plays a role. A closed cranial window and intravital microscopy system was used to monitor diameter changes in pial arterioles (approximately 40 microns) in anesthetized rats. The relative contributions of ADO, NMDA, NO, and neuronal activation to hypoxic cerebrovasodilation were assessed using the blockers 8-sulfophenyltheophylline (8-SPT), MK-801, nitro-L-arginine methylester (L-NAME), and tetrodotoxin (TTX). Two experimental series were studied. In the first, we tested the effects of NOS inhibition, via topical L-NAME (1 mM), on moderate (PaO2 approximately 46 mmHg) then severe (PaO2 approximately 34 mmHg) hypoxia-induced dilation. To confirm that L-NAME was affecting specifically NO-dependent responses, we also examined, in each experiment, the vasodilatory responses to topical applications of NOS-dependent (adenosine diphosphate (ADP); acetylcholine (ACh)) and -independent (sodium nitroprusside (SNP)) agents, in the presence of L-NAME or, in controls, the presence of D-NAME or no added analogue. In the second series, topical suffusions of ADP, ADO, and NMDA were sequentially applied, followed by 5 min exposure to severe hypoxia (PaO2 approximately 32 mmHg). Following return to normoxia, a suffusion of either 8-SPT (10 microM), MK-801 (10 microM), TTX (1 microM), or 8-SPT+MK-801 was initiated (or, in controls, application of a drug-free suffusate was maintained), and the above sequence repeated. In control, TTX, and 8-SPT+MK-801 experiments, baseline conditions were then restored and hypercapnia (PaCO2 = 70-85 mmHg) was imposed. In the series 1 control groups, moderate and severe hypoxia elicited approximately 20% and 35-40% increases in diameter, respectively. L-NAME attenuated ADP- and ACh-induced dilations, did not alter the arteriolar responses to SNP or moderate hypoxia, but prevented further dilation upon imposition of severe hypoxia. This suggested that 45-50% of the severe hypoxia response was NO-dependent. In series 2, 8-SPT blocked the adenosine response and reduced severe hypoxia-induced dilation by 46%. MK-801 predictably blocked NMDA-induced relaxation and reduced the hypoxic response by 42%. When combined, 8-SPT and MK-801 affected hypoxic vasodilation additively. After TTX, the ADP and ADO responses were normal, but NMDA and hypoxia responses were completely blocked. Hypercapnia-induced dilation was unaffected by TTX or 8-SPT+MK-801. The results imply that severe hypoxia-induced release of NO and ADO, and the accompanying pial arteriolar dilation, are wholly dependent on the capacity to generate action potentials in perivascular nerves. The similarity of the L-NAME and MK-801 effects on hypoxic cerebrovasodilation suggests that the NO-dependency, to a large degree, derives from NMDA receptor activation.

Transcranial Doppler sonography indicates critical brain perfusion during hemorrhagic hypotension in dogs.

This study investigated the effects of hemorrhagic hypotension on cerebral blood flow velocity and brain electrical activity (by electroencephalogram [EEG]). Eleven mongrel dogs were anesthetized with isoflurane (1 minimum alveolar anesthetic concentration [MAC]) and catheters were placed into both femoral arteries and veins for mean arterial blood pressure (MAP) measurement, blood withdrawal, and drug administration. Brain temperature, arterial blood gases, and pH were maintained constant. EEG was recorded from temporoparietal recording sites versus a frontal reference. A pulsed transcranial Doppler (TCD) probe (2 MHz, Transpect, Medasonics) was placed on the dura via a temporal bone window to measure mean (Vmean, cm/s) and diastolic blood flow velocity (Vdiast, cm/s) in the middle cerebral artery. At the end of the surgical preparation, isoflurane was discontinued and all animals received fentanyl (bolus, 25 micrograms/kg intravenously (IV); infusion, 50 micrograms.kg-1.h-1 IV) plus 50% N2O/O2 during 30 min of equilibration. After recordings of baseline data, the dogs were hemorrhaged at a rate of 80-100 mL/min. The observation interval was 14 min. EEG spectral edge frequency (SEF 95%) and Vmean did not change when MAP was decreased from 109 +/- 10 to 63 +/- 7 mm Hg. This indicates preserved neuronal function and intact autoregulation of cerebral blood flow. Below MAP of 49 +/- 9 mm Hg, a shift of the EEG to lower frequencies was associated with decreases in Vmean and Vdiast. EEG burst suppression occurred at a MAP of 31 +/- 7 mm Hg, paralleled by a loss of the diastolic flow velocity pattern.(ABSTRACT TRUNCATED AT 250 WORDS)

Analysis of halothane effects on myocardial force-interval relationships at anesthetic concentrations depressing twitches but not tetanic contractions.

BACKGROUND: Tetanic contractions in rat myocardium depend solely on cellular Ca2+ uptake, whereas twitches depend on Ca2+ release from the sarcoplasmic reticulum. Because halothane may cause loss of sequestered Ca2+, the anesthetic was tested for its differential effects on twitch and tetanic forces. The in vitro effects of halothane on the twitch force-interval relationship were then evaluated, using a mathematical model that relates twitch contractile force to the Ca2+ content of intracellular compartments. METHODS: Isometric contractile force was measured in paced (0.4 Hz) rat atrial preparations. The sarcoplasmic reticulum was functionally eliminated using ryanodine (10(-6) M), abolishing twitches. Rapid pacing (20 Hz, 10 s) caused tetanic contractions. The effects of identical halothane exposures on twitches and tetanic contractions were compared. Ca2+ compartment model parameters were extracted from twitch force-interval data, according to a previously employed quantitative procedure. RESULTS: Halothane (0.5-1%) depressed normal twitches, but not tetanic contractions. The anesthetic decreased the amplitude of the steady-state twitch force-frequency relationship, and accelerated the course of mechanical recovery. Halothane (0.5-1%) also accelerated the decay constant for the decline in amplitude of a series of rest-potentiated contractions. The modeling showed that a 20-30% decrease in the recirculating fraction of activator Ca2+ accounts for 0.5% halothane-induced negative inotropy and acceleration of the decay constant. CONCLUSIONS: The differential effect of halothane on twitches and tetanic contractions implies that a functioning sarcoplasmic reticulum is required for halothane-induced negative inotropy. The effects of halothane on the force-interval relationship suggest that halothane reduces the sequestered pool of activator Ca2+.

The role of neuronal nitric oxide synthase in regulation of cerebral blood flow in normocapnia and hypercapnia in rats.

The nitric oxide synthase (NOS) inhibitors, nitro-L-arginine, its methyl ester, and N-monomethyl-L-arginine, have been shown to attenuate resting CBF and hypercapnia-induced cerebrovasodilation. Those agents nonspecifically inhibit the endothelial and neuronal NOS (eNOS and nNOS). In the present study, we used a novel nNOS inhibitor, 7-nitroindazole (7-NI) to examine the role of nNOS in CBF during normocapnia and hypercapnia in fentanyl/N2O-anesthetized rats. CBF was monitored using laser-Doppler flowmetry. Administration of 7-NI (80 mg kg-1 i.p.) reduced cortical brain NOS activity by 57%, the resting CBF by 19-27%, and the CBF response to hypercapnia by 60%. The 60% reduction was similar in magnitude to the CBF reductions observed in previous studies in which nonspecific NOS inhibitors were used. In the present study, 7-NI did not increase the MABP. Furthermore, the CBF response to oxotremorine, a blood-brain barrier permeant muscarinic agonist that induces cerebrovasodilation via endothelium-derived NO, was unaffected by 7-NI. These results confirmed that 7-NI does not influence eNOS; they also indicated that the effects of 7-NI on the resting CBF and on the CBF response to hypercapnia in this study were solely related to its inhibitory action on nNOS. The results further suggest that the NO synthesized by the action of nNOS participates in regulation of basal CBF and is the major, if not the only, category of NO contributing to the hypercapnic CBF response.

Nitrous oxide added to isoflurane increases brain artery blood flow and low frequency brain electrical activity.

Although changes in cerebral blood flow (CBF) and the electroencephalogram (EEG) have been reported with nitrous oxide (N2O) administration, the interaction of these parameters is unclear. The purpose of this study was to measure CBF and EEG during N2O administration in eight patients. A craniotomy was performed and CBF was measured in major brain arteries using a transit time Doppler flowmeter. EEG was recorded bilaterally from frontooccipital leads. Power spectrum analysis was performed on the EEG and power for delta, theta, alpha, and beta frequency bands analyzed over time. Arterial blood pressure was recorded continuously. N2O (66%) was added to the inspired gases during isoflurane anesthesia (0.8% end tidal) under hypocapnic (Paco2 = 29 mm Hg) and normocapnic conditions (Paco2 = 39 mm Hg). During hypocapnia, N2O administration decreased alpha EEG activity and increased delta activity but did not change CBF. During normacapnia, N2O produced similar but greater changes in EEG and increased CBF 39%. In three patients, the isoflurane concentration was increased to 1.6% end tidal during normocapnia. N2O administration in these patients also enhanced delta EEG activity and increased CBF. The slowing of EEG activity with N2O is temporally related to increases in CBF during normocapnia. Hypocapnia abolished the increase in CBF during N2O and attenuated the shift of EEG to delta activity.

The role of nitric oxide in modulating brain activity and blood flow during seizure.

The role played by nitric oxide (NO) in modulating seizure activity and cerebral blood flow (CBF) during seizures was investigated in rats. Seizures were induced with bicuculline (a GABA antagonist, 1.2 mg kg-1, i.v.). Each animal was subjected to an initial bicuculline-induced seizure followed by treatment with either L-nitroarginine (L-NA, a NO synthase inhibitor) or its less active enantiomer D-NA as a 50 mg kg-1 bolus followed by an infusion of 1 mg kg-1 min-1. The animals then received a second bicuculline treatment. Seizure duration was monitored using EEG and CBF was measured with laser-Doppler. There was no difference in seizure duration before or after D-NA administration. Seizure duration doubled from (6 +/- 1 to 12 +/- 2 min p < 0.05) following inhibition of NO synthase with L-NA. The increase in CBF that accompanied the seizure activity paralleled the seizure duration. Our data support the concept that (1) NO acts as an endogenous anticonvulsant, with seizure duration doubling when NO synthase is acutely inhibited, and (2) that NO is not the messenger that couples CBF to metabolism during bicuculline-induced seizures.

Role of nitric oxide and endothelium in rat pial vessel dilation response to isoflurane.

Isoflurane induces cerebral hyperemia. We sought to assess whether isoflurane induces cerebral microvessel dilation in vivo, and if so, to determine whether nitric oxide (NO) and endothelium are involved. By using a rat closed cranial window model, pial arterioles and venules of 30-70 microns in diameter were measured using intravital microscopy. The cerebral microvascular dilatory response was recorded as percent change of diameter from baseline. The pial vessels were suffused with sodium nitroprusside (SNP) or S-nitroso-acetyl-penicillamine (SNAP) to verify intact vascular smooth muscle relaxation function, and with adenosine diphosphate (ADP) and/or acetylcholine (ACh) to verify endothelial NO-generating capability. To isolate NO's role in the cerebral microvascular effects of isoflurane (Protocol I), microvessels were studied with and without nitric oxide synthase (NOS) inhibition by topically applied nitro-L-arginine methyl ester (L-NAME). In controls, L-NAME was replaced by its inactive enantiomer, nitro-D-arginine methyl ester (D-NAME). Mercury light plus fluorescein dye (LD) endothelial injury (Protocol II) was used to delineate an endothelium-mediated mechanism. Subsequently, vasodilator applications were repeated to verify the desired effects of the interventions and followed by suffusion of isoflurane 1%, 2%, and 3% (Protocol I) or isoflurane 3% (Protocol II). Suffusions of SNP, ADP, and ACh induced diameter increases of 15%-30%. NOS inhibition with L-NAME greatly attenuated ADP and ACh responses, but did not alter the SNP response, confirming that NO generation was blocked, but not NO action. These responses were unaffected in D-NAME-suffused rats. Isoflurane dilated arterioles 17% and venules 6% in the presence of D-NAME suffusion.(ABSTRACT TRUNCATED AT 250 WORDS)

The role of endothelium and nitric oxide in rat pial arteriolar dilatory responses to CO2 in vivo.

Using a closed cranial window system and intravital microscopy/videometry, we studied the rat pial arteriolar (30-60 microns) responses to CO2 before and following a light/dye (L/D) endothelial injury or topical application of the nitric oxide synthase (NOS) inhibitor, nitro-L-arginine (L-NA) or its inactive form, D-NA. L/D treatment consisted of intravenous injection of sodium fluorescein and the illumination (for 90 s) of arteriolar discrete segments on the cortical surface with light from a mercury lamp. Functional changes in pial arteriolar endothelium were characterized by evaluating responses to topical application of acetylcholine (Ach, 5 x 10(-4) M) and to intravenous (i.v.) oxotremorine (OXO, a stable blood-brain barrier permeant muscarinic agonist, 1 microgram kg-1 min-1). After the L/D injury, dilation to Ach was absent whereas dilations to the NO donor, S-nitrosoacetyl-penicillamine (SNAP, 10(-5) M) and to CO2 (5%) were unchanged (PaCO2 = 70 mm Hg). Loss of Ach response but intact SNAP response confirmed functional endothelial injury and intact smooth-muscle function. The global endothelium-dependent vasodilation induced by i.v. OXO was markedly attenuated when expanding the L/D injury field from 300 microns to 6 mm in diameter. However, the global vasodilation induced by inhalation of CO2 was still unaffected by this increase in the area of light exposure. This provides evidence that the expanded exposure was capable of impairing global vasodilation resulting from endothelium-dependent stimuli but not from inhalation of CO2. The intact CO2 response despite an endothelial dysfunction suggests that the reported NO dependence of hypercapnia-induced cerebral hyperemia in rats cannot be attributed to an endothelial NO source.(ABSTRACT TRUNCATED AT 250 WORDS)

Nitric oxide (NO) is an endogenous anticonvulsant but not a mediator of the increase in cerebral blood flow accompanying bicuculline-induced seizures in rats.

Neurons synthesize NO, which may act as a retrograde messenger, involved in either potentiating or depressing neuronal excitability. NO may also play a role in the cerebral vasodilatory response to increased neuronal activity (i.e., seizures). In this study, two questions were asked: (1) is NO an endogenous anticonvulsant or proconvulsant substance? and (2) is the cerebral blood flow (CBF) increase accompanying bicuculline (BC)-induced seizures mediated by NO? The experiments were performed in 300-400-g Wistar rats anesthetized with 0.6% halothane and 70% N2O/30% O2. CBF was measured using the intracarotid 133Xe clearance method or laser-Doppler flowmetry. EEG activity was recorded. Chronic treatment (4 days) with nitro-L-arginine (L-NA), a potent NO synthase (NOS) inhibitor (400 mg/kg total), suppressed brain NOS by > 97% and prolonged seizure duration from 6 +/- 1 (saline-treated controls) to 12 +/- 2 min. In the L-NA-treated group, the CBF increase was sustained as long as seizure activity remained, indicating that CBF was still tightly coupled to seizure activity. Interestingly, the supposed inactive enantiomer of L-NA, D-NA, also showed an inhibition of brain NOS activity, ranging from 87 to 100%. The duration of seizures in this group (average 8 +/- 2 min) corresponded directly to the magnitude of reduction in NOS activity (r = 0.83, P < 0.05). Specifically, the D-NA results indicated that NOS inhibition had to exceed 95% before any effect on seizure duration could be seen.(ABSTRACT TRUNCATED AT 250 WORDS)

Protein kinase C suppresses receptor-mediated pial arteriolar relaxation in the diabetic rat.

Cerebral vasodilatory responses are selectively impaired in chronically hyperglycemic, diabetic rats. In this study, we tested the hypothesis that chronic hyperglycemia-induced protein kinase C (PKC) activation can account for the suppression of 2 separate receptor-mediated vascular relaxation processes: (1) endothelium-derived nitric oxide (NO) release, and (2) NO-independent beta-adrenergic receptor (beta-AR) activation. The in vivo reactivity of pial arterioles was evaluated in anesthetized rats (streptozotocin-treated diabetics and controls) using a closed cranial window and intravital microscopy. Compared with controls, diabetic rats showed a substantial attenuation or loss of the arteriolar relaxation response accompanying suffusion of the receptor-linked, NO-dependent agonists, acetylcholine (Ach) and adenosine diphosphate (ADP), and the beta-AR-agonist, isoproterenol (ISO). The vasodilatation induced by the direct NO donor, sodium nitroprusside (SNP), was the same in both groups. In the presence of the PKC inhibitor, staurosporine (STAURO), the Ach, ADP, and ISO responses were, largely restored and the SNP response was unaffected. STAURO produced no changes in Ach, ADP, ISO, or SNP responses in non-diabetic rats. These results suggest that PKC activation in chronically hyperglycemic, diabetic rats suppresses receptor-dependent NO release and desensitizes beta-ARs.