Shigeru Fujiwara

Impairment of endothelium-dependent vasodilation induced by acetylcholine and adenosine triphosphate following experimental subarachnoid hemorrhage.

The effect of subarachnoid hemorrhage (SAH) on endothelium-dependent vasodilation of isolated rabbit basilar artery was examined using an isometric tension recording method. Thirty-five rabbits that had 2 successive blood injections were divided into 3 groups: normal animals (control), 4 days, and 3 weeks after the first SAH. Acetylcholine (ACh) (10(-6)-10(-4) M) and adenosine triphosphate (ATP) (10(-6)-10(-4) M) were used to evoke dose-dependent vasodilation of isolated arterial rings previously contracted by 10(-6) M serotonin. In the animals killed 4 days after the first SAH, both ACh- and ATP-induced relaxation were suppressed, and the degree of relaxation of this group was 38 +/- 4.5% (mean +/- SEM) and 22 +/- 3.9% of the initial contractile tone in response to 10(-4) M ACh and 10(-4) M ATP, respectively. Suppression of the relaxation induced by ATP was seen even in the animals killed 3 weeks after the first SAH. Moreover, pretreatment with hemoglobin (10(-6) and 10(-5) M) inhibited endothelium-dependent vasodilation induced by ACh in the arterial rings from the animals killed 4 days after the first SAH. The present experiments suggest that impairment of the endothelium-dependent vasodilation following SAH may be involved in the pathogenesis of cerebral vasospasm.

Blood-arterial wall barrier disruption to various sized tracers following subarachnoid haemorrhage

SummaryDisruption of the blood-arterial wall barrier in the major cerebral arteries occurs following subarachnoid haemorrhage (SAH) and may be related to the pathogenesis of cerebral vasospasm. Using FITC dextrans of various sizes, the present study was undertaken to determine if the barrier disruption shortly after SAH occurs equally to various sized tracers. Forty-two Sprague-Dawley rats were divided into 5 groups. Four groups were injected with FITC-dextrans of differing molecular weights (MW): FD4 (MW=4,080), FD40 (MW=40,500), FD 70 (MW=71,400), and FD 150 (MW=156,900). One group was injected with horseradish peroxidase (HRP: MW=40,000). Each group was further divided into two subgroups: with or without SAH. SAH was induced by injecting arterial blood into the cisterna magna. To assess the integrity of the blood-arterial wall barrier by transmission electron microscope, the tracers were intravenously injected prior to sacrificing the animals. The groups without SAH showed no permeability of tracers into the subendothelial spaces of the basilar arteries. In contrast, with the exception of FD 150, FITC-dextrans (FD 4, FD 40, FD 70) were noticed in the subendothelial spaces. The distribution of FITC-dextrans in the elastic lamina was similar to that of HRP. These results suggest that barrier disruption occurs with a wide range of molecular sizes of FITC-dextrans, although there seems to be some limitation to the permeation of the larger molecules. The present study suggests that the mechanism of barrier disruption of the major cerebral arteries in the acute stage following SAH may be vesicular rather than by separation of tight junctions.

The effects of hyperosmolar solutions on cerebral arterial smooth muscle.

The present study was conducted to clarify the effect of hyperosmolar solutions on the constrictor responses of cerebral arteries to vasoactive agents, in vitro. The canine basilar arteries under resting tension were slightly relaxed with both mannitol (0.5, 1 and 2%) and sucrose (1, 2, and 4%). Constrictor responses of canine basilar arteries to 40 mM K+, 10(-7) M serotonin or 10(-6) M prostaglandin F2 alpha (PGF2 alpha) were markedly suppressed by pretreatment with either mannitol or sucrose. The rate of suppression correlated well to osmolarity changes in the Krebs solution. When the specimens were incubated in Ca++-free medium, 10(-6) M PGF2 alpha elicited small contractions. Addition of 1 mM Ca++ to the bath promptly elicited larger contractions. The large contractions in response to the influx of extracellular Ca++ were markedly suppressed by pretreatment with mannitol or sucrose, while the small contractions induced by intracellular Ca++ were not inhibited. In addition, the contractions induced by the addition of Ca++ to the specimens depolarized with 80 mM K+ in Ca++-free medium were dose-dependently inhibited with either mannitol or sucrose, while the caffeine-induced contractions in Ca++-free medium were not altered by mannitol. These results suggest that hyperosmolar solutions produce non-specific vasodilation of cerebral arteries by inhibiting the influx of external Ca++ rather than the release of intracellularly stored Ca++. This direct vasodilatory effect may account in part for the transient increase of cerebral blood flow following administration of hyperosmolar mannitol.

Barrier disruption in the major cerebral arteries after experimental subarachnoid hemorrhage in spontaneously hypertensive and normotensive rats.

The effects of experimental subarachnoid hemorrhage (SAH) on the blood-arterial wall barrier in the major cerebral arteries were studied in 24 spontaneously hypertensive rats (SHR) and 13 Sprague-Dawley rats (SDR). Horseradish peroxidase (HRP) was given intravenously before killing the animals to assess the integrity of the barrier. In the acute experimental group, transient elevation of intracranial pressure (ICP) and systemic arterial pressure produced by cisternal injection of whole blood, saline solution, or Elliotts B solution resulted in extensive disturbance of the blood-arterial wall barrier. In the chronic group, only the cisternal injection of whole blood in SHR brought about an extensive and marked disturbance of the arterial permeability. These results suggest that: (a) early breakdown of the blood-arterial wall barrier seems to be due to a sudden rise in the ICP or arterial pressure; (b) in the chronic experiments, the subarachnoid clot is the most important factor responsible for the permeability changes; and (c) in the chronic SAH experiments, the blood-arterial wall barrier seems to be more vulnerable in SHR than in Sprague-Dawley rats. Due to the well-known similarities between SHRs and hypertensive human beings, patients with chronic hypertension should be considered at high risk after SAH for extensive blood-arterial wall barrier disturbances.

Etiology of the disruption in blood-arterial wall barrier following experimental subarachnoid hemorrhage

Aneurysmal subarachnoid hemorrhage is associated with a sudden rise in intracranial pressure, acute arterial hypertension, and subarachnoid blood. The role that each of these factors may play in the development of the acute barrier disruption of the major cerebral arteries following subarachnoid hemorrhage was investigated in 42 rabbits. Horseradish peroxidase was given intravenously to assess the integrity of the barrier by transmission electron microscopy. Permeation of the tracer into the vessel was noted only in animals with increased intracranial pressure. A sudden rise in intracranial pressure is suggested to trigger acute barrier disruption following subarachnoid hemorrhage.

Presynaptic inhibitory action of adenosine on neuromuscular transmission in the canine cavernous carotid artery.

We investigated the effect of adenosine on neurogenic contraction of the canine cavernous carotid artery, using an isometric tension recording device and transmural nerve stimulation. Adenosine, in concentrations under 10(-5)M, had no relaxing effect on the contractions produced by high [K]o solution or 10(-5)M norepinephrine. Transmural nerve stimulation (stimulus: 1 msec duration, 100V intensity) evoked a frequency-dependent contraction, which was abolished by 3 X 10(-7)M tetrodotoxin. Adenosine in concentrations of 10(-6)M and 10(-5)M, inhibited the neurogenic contraction at each frequency, more so in the low frequency range. This inhibitory effect of adenosine was significantly antagonized by 10(-5)M theophylline. Pretreatment with 2 X 10(-8)M dipyridamole had no effect on neurogenic contractions, but augmented the inhibitory effect of adenosine. 10(-5)M theophylline did not augment the neurogenic contractions. The findings that both dipyridamole and theophylline failed to affect the neurogenic contractions in the absence of adenosine suggests that the presynaptic autoinhibition mechanism of adenosine may not be involved in neuromuscular transmission in this tissue. These results suggest that there is a presynaptic adenosine receptor in the nerve terminal which inhibits the release of neurotransmitter in canine cavernous carotid artery. It is also probable that the vasodilating effect of adenosine in the cavernous carotid artery is mainly due to its inhibitory effect on neurotransmission rather than to a direct relaxing effect on smooth muscle.