Blockage Of Blood Flow Research Articles

Rapid appearance of pathological changes of neurons and glia cells in the cerebellum of microsphere-embolized rats

Neuropathological changes in the cerebellar cortex of microsphere-embolized rats were studied at 30 min and 3 h after the embolism. Necrotic processes including a sponge-like vacuolation in the molecular layer, a vague outline of some Purkinje cells, and a few pyknotic granule cells having small and dark profiles were identified at sometime between 30 min and 3 h after microsphere-induced embolism in Nissl staining. Glial fibrillary acidic protein staining shows an apparent reduction in the number of Bergmann glial processes in some of the areas where there was necrosis of the molecular layer and poor astroglia processes in the areas subjacent to the pyknotic granule cells. These data demonstrate that within a short time, microsphere-induced cerebral ischemia produces necrosis of cerebellar neurons (i.e. Purkinje and granule cells) and changes in cerebellar glia cells (i.e. Bergmann and astroglia cells), and that these neuropathological changes are secondary phenomenon caused by microsphere blockage of cerebellar blood flow.

Microsurgical intraluminal middle cerebral artery occlusion model in rodents

Focal brain ischemia induced in rodents by occlusion of the middle cerebral artery (MCA) is a widely used paradigm of human brain infarct. The objective of this study is to compare the effectiveness and reproducibility of MCA filament occlusion model in rats and mice. A total of 140 rodents (69 rats and 71 mice) were operated. Ninety-five animals were subjected to MCA occlusion; the surgical procedure consisted of introducing an uncoated surgical nylon monofilament into the cervical common carotid artery (CCA) and advancing it intracranially to permanently block blood flow into the right MCA. Forty-five sham-occluded rodents underwent CCA ligation. Surgical success, autopsy confirmed success and mortality rate were evaluated. Effective MCA occlusion was confirmed by the evidence of motor neurological deficit, by histopathology, immunohistochemistry (IHC) and reverse transcriptase-polymerase chain reaction (RT-PCR). IHC was performed in a randomly selected number of animals to detect the protein product of monocyte chemoattractant protein-1. The brain tissue in mice was examined by RT-PCR for the expression of macrophage inflammatory protein-1 alpha mRNA. Surgical success rate was 89% in the rats, significantly lower than that in the mice (100%, P < 0.05). Autopsy confirmed success rate in the rats, 60%, was also significantly different from that in the mice (92.5%, P < 0.001). The operative mortality rate was 4.3% in the rats and 15% in the mice. The present study demonstrates that the microsurgical filament occlusion of the MCA can be more successfully performed in mice. The lower rate of success in rats seems to be as a result of the architecture of the carotid canal in this animal. No previous reports, using a considerable number of animals, have compared the feasibility of intraluminal model in the rat with that in the mouse.

Purging Plaques

After you wash down a delectable cream-filled doughnut with a swig of cappuccino, cells in your arteries could also start gorging on fat, setting the stage for atherosclerosis. A new study suggests that coaxing these plaque-spawning cells to spit out their excess cholesterol might prevent heart disease. The discovery could lead to the development of drugs that thwart atherosclerosis by blocking the first step in plaque formation. Best known for slurping up bacteria, immune cells called macrophages also eat cholesterol, helping govern its concentration in the blood. Atherosclerosis starts when macrophages binge. The cells slip into the wall of an artery, perhaps drawn by an injury. Once ensconced in the vessel, they fill up on cholesterol, triggering the growth of fatty deposits on the vessel walls that can eventually reduce or block blood flow. Proteins called liver X receptors (LXRs) spur the liver to break down cholesterol; they also stimulate macrophages to eject cholesterol, allowing it to be spirited away for destruction. Because LXRs drive down blood cholesterol levels, drugs that stimulate the receptors might halt or reverse atherosclerosis. In May, molecular biologist Peter Tontonoz of the University of California, Los Angeles, and colleagues showed that tickling the receptors with a synthetic compound reduced plaque buildup in mice by more than one-third. However, several studies have found that such treatments also boost levels of blood triglycerides--which hike the risk of heart disease--probably through LXRs' actions in the liver or intestines. Tontonoz teamed with molecular biologist Rajendra Tangirala of X-Ceptor Therapeutics in San Diego, California, and colleagues to see whether stimulating LXRs only in macrophages could avert this side effect. The researchers irradiated atherosclerosis-prone mice to destroy their white blood cells and then gave the animals a new set of macrophages by means of a bone-marrow transplant. The rodents received marrow either from normal mice whose macrophages carry working LXRs or from mice that lack receptors. The mice injected with marrow that carries functional receptors showed 80% less plaque in their aortas without raising triglyceride values. The results suggest that LXR activity in macrophages hampers fatty buildup, probably by prodding the cells to dump their excess cholesterol, says Tangirala: "Clearly, there is a direct link between LXRs in macrophages and susceptibility to atherosclerosis." The study makes LXRs a prime target for artery-clearing drugs, says molecular biologist David Moore of Baylor College of Medicine in Houston, Texas. The results also raise the possibility that patients with high cholesterol levels might tote faulty versions of LXR, adds Steven Kliewer of the University of Texas Southwestern Medical Center in Dallas. But transforming the discovery into a treatment poses a huge challenge. Scientists will have to craft a drug that goads LXRs in macrophages without tweaking them in the liver or intestines. Nobody knows yet how to achieve that kind of selectivity. "Will it be difficult? Yes, but it's not impossible," says Moore. If the idea pans out, such drugs could spur macrophages to purge themselves of excess cholesterol and keep blood flowing, even if you can't resist eating the last doughnut in the box. --Mitch Leslie R. K. Tangirala, E. D. Bischoff, S. B. Joseph, B. L. Wagner, R. Walczak, B. A. Laffitte, C. L. Daige, D. Thomas, R. A. Heyman, D. J. Mangelsdorf, X. Wang, A. J. Lusis, P. Tontonoz, I. G. Schulman, Identification of macrophage liver X receptors as inhibitors of atherosclerosis. Proc. Natl. Acad. Sci. U.S.A. , 22 August 2002 [e-pub ahead of print]. [Abstract] [Full Text]

In Vivo Assessment of Calcium Alginate Gel for Endovascular Embolization of a Cerebral Arteriovenous Malformation Model Using the Swine Rete Mirabile

We sought to assess the stability of calcium alginate as an embolic agent in an animal model of a cerebral arteriovenous malformation (AVM). Swine cerebral AVM models were used to test the injectability, radiographic visualization, mechanical stability, and biocompatibility of calcium alginate as an occlusive agent. The swine cerebral AVM model included a carotid-to-jugular anastomosis to increase flow to the rete mirabile (RM), thereby simulating the pressure gradient and shunted blood flow of an AVM. Alginate and the reactive component, calcium chloride, were injected from double-lumen microcatheters to form a complete RM occlusion in the "acute swine" AVM model and a partial occlusion in a "survival swine" model. Angiographic and histological results verified complete occlusion of the left RM in acute animals when alginate was injected in stages. Partial RM occlusion in the survival animals blocked blood flow to the inferior portion of the RM but left flow open to the superior portion of the RM and the circle of Willis. One-week survival results showed that the alginate remained a stable occlusive material. Histological results showed a minor bioactive response and encapsulation of the alginate polymer, thereby increasing the stability and effective occlusion of the embolization material. Calcium alginate proved to be an effective endovascular occlusion material that blocked blood flow to the swine RM. The swine AVM models provided assessment of alginate injectability and effective occlusion and provided initial in vivo characteristics of alginate stability and biocompatibility.

Summaries for patients. Associations between peripheral arterial disease and leg function.

Summaries for Patients18 June 2002Associations between Peripheral Arterial Disease and Leg FunctionSearch for more papers by this authorAuthor, Article, and Disclosure Informationhttps://doi.org/10.7326/0003-4819-136-12-200206180-00003 SectionsAboutFull TextPDF ToolsAdd to favoritesDownload CitationsTrack CitationsPermissions ShareFacebookTwitterLinkedInRedditEmail What is the problem and what is known about it so far?The blood vessels that carry blood from the heart to the legs are called peripheral arteries. Sometimes, fatty buildup in the artery walls reduces or blocks blood flow through these arteries, a condition called peripheral arterial disease (PAD). Slightly more than 10% of Americans older than 65 years of age have PAD. The condition is more common in people who smoke or have high cholesterol levels or diabetes mellitus. Peripheral arterial disease reduces blood supply to tissues. It can cause pain in one or both calves that is ... Author, Article, and Disclosure InformationAffiliations: The summary below is from the full report titled “The Ankle Brachial Index Is Associated with Leg Function and Physical Activity: The Walking and Leg Circulation Study.” It is in the 18 June 2002 issue of Annals of Internal Medicine (volume 136, pages 873-883). The authors are MM McDermott, P Greenland, K Liu, JM Guralnik, L Celic, MH Criqui, C Chan, GJ Martin, J Schneider, WH Pearce, LM Taylor, and E Clark.Summaries for Patients are a service provided by Annals to help patients better understand the complicated and often mystifying language of modern medicine.Summaries for Patients are presented for informational purposes only. These summaries are not a substitute for advice from your own medical provider. If you have questions about this material, or need medical advice about your own health or situation, please contact your physician. The summaries may be reproduced for not-for-profit educational purposes only. Any other uses must be approved by the American College of Physicians-American Society of Internal Medicine. PreviousarticleNextarticle Advertisement FiguresReferencesRelatedDetailsSee AlsoThe Ankle Brachial Index Is Associated with Leg Function and Physical Activity: The Walking and Leg Circulation Study Mary McGrae McDermott , Philip Greenland , Kiang Liu , Jack M. Guralnik , Lillian Celic , Michael H. Criqui , Cheeling Chan , Gary J. Martin , Joseph Schneider , William H. Pearce , Lloyd M. Taylor , and Elizabeth Clark Metrics 18 June 2002Volume 136, Issue 12Page: I-32KeywordsAnkle brachial indexArteriesBlood pressureBlood vesselsDiabetes mellitusExerciseHeartHypercholesterolemiaPeripheral vascular diseaseWalking ePublished: 18 June 2002 Issue Published: 18 June 2002 Copyright & PermissionsCopyright © 2002 by American College of Physicians. All Rights Reserved.PDF downloadLoading ...

Hemodynamics in the left gastric vein after endoscopic ligation of esophageal varices combined with sclerotherapy.

We examined the changes in portal hemodynamics after endoscopic variceal ligation (EVL) combined with endoscopic injection sclerotherapy (EIS) in relation to post-treatment relapse. The present study included 93 patients who underwent EVL-EIS combination therapy. Portal hemodynamics were examined by Doppler ultrasonography and percutaneous transhepatic portography (PTP). Therapy with EVL-EIS resulted in the complete disappearance of varices in 89 of 93 patients. Cumulative relapse-free rates (Kaplan-Meier method) were 75.8 and 50.2%, respectively, 1 and 3-5 years after treatment. At the end of treatment, the flow in the left gastric vein was examined by Doppler ultrasonography. In 50 of 63 patients, the flow remained hepatofugal. In 23 of these patients, PTP was performed at the end of treatment; selective left gastric venography did not reveal any palisade zone vessels or varices. However, fine blood vessels were seen around the lower esophagus in nine patients, only the paraesophageal vein was found in 10 patients and these two findings were present in four patients, indicating that collateral blood flow remained in the lower esophagus in 13 of 23 patients. These findings suggest that frequent relapse of varices results from insufficient blockage of blood flow from the left gastric vein to the lower esophagus. However, in patients with a patent paraesophageal vein, long-term effects obtained by EVL-EIS combination therapy were satisfactory. The pattern of the development of collateral left gastric veins represents important hemodynamic changes that predict the long-term prognosis of patients after treatment.

Restenosis: A challenge to angioplasty

Fatty deposits clog the coronary arteries blocking blood flow to the heart muscles. This leads to coronary artery diseases. The therapeutic approach is to either provide a by-pass or clear the block by a procedure called angioplasty. However, angioplasty has a high rate of restenosisrenarrowing of the artery in due course. Scientists are looking at various options to prevent restenosis. Application of ionising radiation to the site of angioplasty is one such option.

Effects of Interrupted and Uninterrupted Occlusion of the Basilar Artery on Cerebral Blood Flow, and on Neurological and Histological Outcome in Rats with Subarachnoid Hemorrhage

Most neurosurgeons consider temporary vessel occlusion for aneurysmal clipping an effective technique that facilitates dissection between the aneurysm and the parent vessel. It is generally believed that repeated short periods of cerebral ischemia are safer for the brain than a single long episode. The aim of this study was to identify whether interrupted and uninterrupted vessel occlusion differs with regard to changes in brain tissue and cerebral hemodynamics after subarachnoid hemorrhage (SAH). Fifty Spraque Dawley rats (300–350 g) were placed under general anaesthesia and ventilated. The basilar artery was exposed through a transclival approach. Baseline local cerebral blood flow (LCBF) values was measured, and then the basilar artery was punctured, causing subarachnoid hemorrhage (SAH). Group I (n = 24) was subjected to 60 min of interrupted basilar artery occlusion, defined as 5 min of reperfusion after every 10 min of occlusion, group II (n = 26) 60 min of uninterrupted artery occlusion. Three days after completion of the experiment, each rat was neurologically evaluated and decapitated. Coronal brain slices were obtained and stained to assess infarct volume. Immediately after SAH, LCBF fell by 58% in group I, and by 52% in group II. In group I, each ischemic insult brought a similar reduction in LCBF, and after each release of the occlusion there was a rapid rise in flow. In group II, the LCBF values dropped initially and remained at low levels until the end of the study. The 2, 3, 5 triphenyltetrazolium chloride stained sections showed similar volumes of brainstem infarction in both groups (38.3 ± 9.2 mm 3 vs. 34.3 ± 8.7 mm 3, respectively; p > 0.05). The results suggest that there is no neuroprotective advantage to either interrupted or uninterrupted temporary blockage of blood flow during neurovascular procedures after SAH in the basilar artery region.

Polymerization and Three Dimensional Reconstruction of Deoxy-Sickle Cell Hemoglobin Fibers in High and Low Phosphate Buffers

Abstract The amino acid substitution (B Glu → G6 Val) results in the conversion of Hemoglobin A (HbA) to sickle cell hemoglobin(HbS) which is responsible for sickle cell disease. Under physiological conditions this substitution causes a reduction of the solubility of HbA from about 340 mg/ml to 165 mg/ml (for HbS). One consequence of the reduction in solubility is that HbS polymerizes to form long fiber like structures about 240Å in diameter. The formation of these fibers causes sickle cell disease. The fibers fill the red cell and cause it to assume a characteristic sickle shape. More significantly the fibers cause the red cell to become rigid and, as a result, sickled cells can block blood flow in the capillaries. Understanding the polymerization process in detail is important for understanding the pathophysiology of sickle cell disease and for developing a specific therapy that could be used in its treatment.

Fluid mechanics of vascular systems, diseases, and thrombosis.

The cardiovascular system is an internal flow loop with multiple branches circulating a complex liquid. The hallmarks of blood flow in arteries are pulsatility and branches, which cause wall stresses to be cyclical and nonuniform. Normal arterial flow is laminar, with secondary flows generated at curves and branches. Arteries can adapt to and modify hemodynamic conditions, and unusual hemodynamic conditions may cause an abnormal biological response. Velocity profile skewing can create pockets in which the wall shear stress is low and oscillates in direction. Atherosclerosis tends to localize to these sites and creates a narrowing of the artery lumen--a stenosis. Plaque rupture or endothelial injury can stimulate thrombosis, which can block blood flow to heart or brain tissues, causing a heart attack or stroke. This small lumen and elevated shear rate in a stenosis create conditions that accelerate platelet accumulation and occlusion. The relationship between thrombosis and fluid mechanics is complex, especially in the post-stenotic flow field. New convection models have been developed to predict clinical from platelet thrombosis in diseased arteries. Future hemodynamic studies should address the complex mechanics of flow-induced, large-scale wall motion and convection of semisolid particles and cells in flowing blood.

Decrease in intravesical saline volume during isovolumetric cystometry in the rat

This study was undertaken to examine the change in intravesical saline volume during isovolumetric cystometry in the urethane anesthetized female rat. The ureters were transected bilaterally and their distal ends were ligated. To prevent leakage of intravesical fluid, the proximal urethra was ligated after inserting a urethral catheter into the bladder. In 13 rats in which the bladder was filled with different volumes of saline between 0.3 and 2.0 ml and maintained under isovolumetric conditions for 3 hours, intravesical volume decreased (4-79%) when initial intravesical saline volume was equal to or greater than 0.6 ml (n = 9). In 9 rats in which intravesical volume decreased, mean final volume was 0.68 +/- 0.09 ml. The percentage change in intravesical volume (y) significantly depended on initial volume (x) (y = -42x + 17, n = 13). In 7 rats in which the proximal urethra was ligated and the bladder was filled with different volumes of soybean oil between 0.25 and 2.0 ml, intravesical volume did not change. In 8 rats in which the bladder neck was ligated around a urethral catheter to block blood flow to the bladder and in which the bladder was filled with different volumes of saline (0.3-1.8 ml), intravesical volume decreased when initial volume was equal to or greater than 1.35 ml. These results demonstrate that intravesical saline is absorbed from the normal bladder wall when intravesical volume is greater than the volume (0.6 ml) necessary to evoke the micturition reflex in urethane anesthetized rats.

Acute Coronary Syndromes: 1. The Platelet's Role

Platelets play key physiologic roles in the hemostatic response to vascular injury. But thrombi that form in the absence of vessel wall damage may either disrupt or completely block blood flow. A better understanding of platelet pathophysiology promises to lead to improved therapy of myocardial infarction, unstable angina, and related syndromes.

Development of an Occluder Device for Closure of Patent Ductus Arteriosus

Background：Surgical correction of patent ductus arteriosus (PDA is relatively safe and effective since it does not remain in the category of open-heart-surgery. Although the surgical practice for PDA is performed in almost all hospitals, they contain the problems of anxiety of patients, remained surgical wounds on patients’ chests and complications of surgery and general anesthesia. Recently non-surgical methods for the obstruction of PDA have been developed and some of them including buttoned devices are used now. The success rates of these methods approach to 84%. But the problems of embolization, incomplete closure, hemolysis, stenosis of aorta and left pulmonary artery have been reported. We invented new PDA occluder , using stainless steel wire and polyurethane foam. Therefore we investigated the efficacy of occluding blood flow with the new PDA occluder in the vessels of experimental animals. Method：Using 304 stainless steel wire which is selfexpandable stent, two star-shaped frames were made, each frame forming cone and facing the other’s tip. And in the center of the frames polyurethane foam was inserted. 316L stainless steel wire was used to fix the elements described above and some portion of the wire was extracted outside of the frames, shaping hook or round loop with which the occluder could be pulled out in case of misplacement. To create the similar situation to PDA, we made shunts from artery to vein between carotid arteries and jugular veins with surgical bypass grafts or made shunts of direct artery to vein connections without grafts in 4 dogs and 1 pig. Through 8F sheath, we deployed the occluders into the shunts made of 5 grafts or made of 3 arterial ends. Also the occluders were inserted into the femoral artery of dog and iliac artery of pig. After deployment of occluders, angiograms were performed to obscure the efficacy of blocking blood flow and follow-up angiogrms were done in one and two weeks. The animals were sacrificed in one and two weeks to get the tissues including

Latency of muscle chemoreflex to vascular occlusion of active muscle during dynamic exercise

When oxygen delivery to active muscle is too low for the ongoing rate of metabolism, metabolites accumulate and activate a muscle chemoreflex that raises arterial pressure. During static muscular contractions, the latency of the onset of increments in sympathetic activity attributed to the muscle chemoreflex is long (1-2 min). This long latency might be caused by slow accumulation of metabolites attributable to low rates of metabolism. Because shortening contractions at a given force per unit time have a much higher energy cost than do static contractions, the muscle chemoreflex should have a much shorter latency during dynamic exercise than during static contractions, and the latency should shorten further with rising exercise intensity. To test these ideas, the latency to the onset of the rise in arterial pressure induced by the muscle chemoreflex following vascular occlusion of active muscle was measured in four dogs exercising on a treadmill. During steady-state exercise of mild to moderate intensity, pressor responses to muscle ischemia were elicited by rapid, complete occlusion of the terminal aorta; this procedure mimics the blockage of muscle blood flow that occurs normally during static contractions. There was a statistically significant effect of exercise intensity on latency (P < 0.001). The latency was 23.5 +/- 4.5, 16.4 +/- 5.6, and 10.1 +/- 2.3 s (means +/- SE) at 3.2 km/h 0% grade, 6.5 km/h 0% grade, and 6.5 km/h 10% grade, respectively. Also, the rate of rise of arterial pressure during chemoreflex activation increased progressively with rising exercise intensity from 0.8 +/- 0.2 mmHg/s during exercise at 3.2 km/h 0% grade to 2.0 +/- 0.5 mmHg/s during exercise at 6.5 km/h 10% grade. Thus the latency of the muscle chemoreflex in response to vascular occlusion during mild dynamic exercise is shorter than has been reported during static contractions of moderate intensity.

BLOOD FLOW IN ARTERIES

▪ Abstract Blood flow in arteries is dominated by unsteady flow phenomena. The cardiovascular system is an internal flow loop with multiple branches in which a complex liquid circulates. A nondimensional frequency parameter, the Womersley number, governs the relationship between the unsteady and viscous forces. Normal arterial flow is laminar with secondary flows generated at curves and branches. The arteries are living organs that can adapt to and change with the varying hemodynamic conditions. In certain circumstances, unusual hemodynamic conditions create an abnormal biological response. Velocity profile skewing can create pockets in which the direction of the wall shear stress oscillates. Atherosclerotic disease tends to be localized in these sites and results in a narrowing of the artery lumen—a stenosis. The stenosis can cause turbulence and reduce flow by means of viscous head losses and flow choking. Very high shear stresses near the throat of the stenosis can activate platelets and thereby induce thrombosis, which can totally block blood flow to the heart or brain. Detection and quantification of stenosis serve as the basis for surgical intervention. In the future, the study of arterial blood flow will lead to the prediction of individual hemodynamic flows in any patient, the development of diagnostic tools to quantify disease, and the design of devices that mimic or alter blood flow. This field is rich with challenging problems in fluid mechanics involving three-dimensional, pulsatile flows at the edge of turbulence.

A relationship between apoptosis and flow during programmed capillary regression is revealed by vital analysis.

Previous analyses of developmentally programmed capillary regression suggested two distinct causes of vascular endothelial cell (VEC) death. The first appeared to be macrophage-dependent (Lang, R. A. and Bishop, M. J. (1993) Cell 74, 453-462) while the second was proposed to result from cessation of blood flow (Lang, R. A., Lustig, M., Francois, F., Sellinger, M. and Plesken, H. (1994). Development 120, 3395-3403). Combined, these analyses suggested a model in which initial, macrophage-mediated endothelial cell apoptosis blocked blood flow within a capillary segment and, as a consequence, caused apoptosis of all remaining cells in the affected segment. In the current study, we have tested this model using a new method that combines vital and histological analyses as a means of determining the fate of whole capillary segments and individual cells in vivo. This technique revealed that one of the first events in regression was the apoptosis of a single VEC in otherwise normal, flowing capillary segments (initiating apoptosis). These isolated, dying VECs projected into and restricted the capillary lumen, imposing either a temporary or permanent block to blood flow. Following cessation of flow, synchronous apoptosis of VECs occurred (secondary apoptosis). In addition, a quantitative analysis revealed a reciprocal relationship between plasma flow and VEC apoptosis. These observations are consistent with a model for capillary regression in which macrophages induce apoptosis in a limited number of VECs and, as a consequence of a block to blood flow, also cause apoptosis in those remaining.

Pre-and peristroke treatment with the adenosine kinase inhibitor, 5′-deoxyiodotubercidin, significantly reduces infarct volume after temporary occlusion of the middle cerebral artery in rats

The adenosine kinase inhibitor, 5′-deoxyiodotubercidin (5dITU), was examined in a rat focal stoke model with temporary (105 min) middle cerebral artery occlusion (MCAO) followed by a 24 h recovery period. Inhibition of this adenosine metabolizing enzyme indirectly enhances the actions of endogenous adenosine without inducing cardiovascular side effects. Such effects could limit the potential clinical application of any approach targeting adenosine receptor activation. MCAO was accomplished with a transluminal 4-0 nylon suture inserted through the common carotid artery to block blood flow at the origin of the MCA. Treatment with 5dITU 30 min prior to and 5 h after MCAO resulted in a dose dependent (0.1–0.5 mg/kg, i.p.) reduction in infarct volume. A significant ( P = 0.02) 44% reduction (control, 265 ± 35 mm 3; treated, 149 ± 30 mm 3) was observed at 0.5 mg/kg. However, at the highest dose examined (1.0 mg/kg) infarct volume was unaffected. To assess the potential for acute (i.e. post-occlusion) treatment, 5dITU was administered (0.33 mg/kg, i.v.) successively at each of 0.5, 1.75 and 3.5 h after MCAO. Post-occlusion treatment resulted in a significant ( P = 0.037) 32% reduction in infarct volume (control, 314 ± 34 mm 3; treated, 212 ± 28 mm 3). At this dose there were no apparent changes in a number of physiological parameters monitored over the period of MCAO. The present study shows that intervention with an adenosine kinase inhibitor in an ischemic brain injury model is neuroprotective whether treatment is begun prior to or just after MCAO.

Morphological and Physiological Consequences of Parasites Encysted in the Bulbus Arteriosus of an Estuarine Fish, the Sheepshead Minnow, Cyprinodon variegatus

The contribution of parasites to host population regulation is undefinable without knowledge of parasite effects on individual host performance and survival. Effects are best determined by examining performance of differentially parasitized hosts under the varying environmental conditions that characterize the host's habitat. The sheepshead minnow, Cyprinodon variegatus, an estuarine fish, is heavily parasitized in the bulbus arteriosus by the heterophyid trematode Ascocotyle pachycystis in semi-enclosed shallow bodies of water in northwestern Florida. Laboratory experiments were conducted to examine the morphological and physiological effects of parasitization of these fish. Differentially parasitized fish were compared for differences in ventricle weight and swimming performance. Parasitized fish ventricles were hypertrophied due to mechanical blockage of normal blood flow by metacercariae in the bulbus. Swimming performance generally was reduced by the presence of parasites, which had their most significant negative effect at cold temperatures and low dissolved oxygen levels.

Investigation of possible mechanisms of hepatic swelling and necrosis caused by acetaminophen in mice

Vascular congestion and liver swelling have long been recognized as features of the hepatotoxic effects of acetaminophen (AAP) in mice and rats and have been proposed as contributing factors to the eventual extent of necrosis produced. Neutrophil accumulation in the hepatic microcirculation has been proposed as being responsible for the blockage of hepatic blood flow and thereby the expansion of the region of damage. We therefore determined in mice the effects of hepatotoxic doses of AAP on the messenger RNA for intercellular adhesion molecule-1 (ICAM-1), which is a critical determinant of neutrophil adhesion, activation and ultimately of neutrophil-mediated tissue injury. Hepatotoxic doses of AAP did not upregulate ICAM-1 messenger RNA. However, doses of bacterial lipopolysaccharide (LPS) did cause a rapid and dramatic increase in ICAM-1 message, which was accompanied by a much greater hepatic accumulation of neutrophils, but which led to only scattered single cell necrosis. In addition, we investigated the effects of pentoxifylline (PTX) on AAP-induced vascular congestion and on hepatic necrosis as evaluated histologically and by measurement of plasma transaminase activities. Although PTX has been shown to increase blood cell deformability and improve vascular perfusion in a number of animal models of restricted blood flow, and is used in humans for the treatment of intermittent claudication, we found no decrease in AAP-induced hepatic swelling or in AAP-induced necrosis in response to PTX. With some dosing regimens, PTX-treated animals proved to be slightly more susceptible to AAP, which may be related to the reported potentiation of the cytotoxicities of a number of alkylating anti-cancer drugs by PTX and other methylxanthines. We conclude from these studies that upregulation of ICAM-1 and subsequent adhesion and vascular plugging by neutrophils are not significant determinants of AAP-induced liver swelling and necrosis and that whatever hemorheological advantages PTX might offer in AAP-induced hepatic damage appear to be overshadowed by effects that potentiate the toxic responses.

Embolotherapy of massive duodenal hemorrhage.

Eleven patients with massive duodenal hemorrhage were treated by emergent embolization. Bleeding originated from duodenal ulcer in three patients, from duodenal tumor in one, from ruptured pancreaticoduodenal artery pseudoaneurysm in three, and from ruptured gastroduodenal artery pseudoaneurysm in four. Complete hemostasis was obtained immediately after embolotherapy in all cases. Three of these patients died during the hospitalization period, one of whom from duodenal infarction and pancreas necrosis induced by embolization. In three patients with duodenal ulcer, complete hemostasis was obtained only by the gastroduodenal artery embolization with Gelfoam particles. Seven patients with pseudoaneurysms of the gastroduodenal artery or its branches required not only blockage of blood flow from the celiac artery but also the superior mesenteric artery for complete hemostasis. Therefore, in patients presenting with duodenal hemorrhage, the possibility of dual blood supply to the duodenum should be considered. Emergent embolization represents a useful alternative to surgery for massive duodenal hemorrhage, but it carries a risk of complications in patients with previous gastroduodenal surgery or significant visceral atherosclerosis.