Charles P. Olinger

Measurements of acute cerebral infarction: lesion size by computed tomography.

As part of a prospective therapy study of 65 patients with acute, nonhemorrhagic, cerebral infarction, computed tomographic scans of the head were obtained at admission, 7-10 days, and 3 months. The scans were analyzed for the presence, site, size, and volume measurement of the infarction. At 7-10 days, the mean infarction volume as measured by computed tomography was 55 cm3 or about 4 x 4 x 3.5 cm (range = 0-507 cm3). At 3 months, the mean infarction volume decreased by 25% to 41 cm3. For the 26 scans showing infarction at the time of admission, the mean lesion volume was 33 cm3 at admission, 51 cm3 at 7-10 days, and 49 cm3 at 3 months. With lesion size at 7-10 days expressed as percentage of total brain volume, the mean infarction size was only 5%. Of the 49 patients with lesions revealed by computed tomography at 7-10 days, 20 had an infarction of 1% or less of total brain volume, while only six had an infarction of 20% or more of total brain volume. The lesion volumes as measured by the 7-10-day computed tomography correlated with the neurologic examination scores on admission (Spearmans rank-order correlation = 0.78) and with the scores at 1 week (Spearmans rank-order correlation = 0.79).

Hyperdense middle cerebral artery: incidence and quantitative significance

SummaryThe hyperdense middle cerebral artery sign (HMCAS) is recognized as a CT finding that indicates thrombus or embolus within the middle cerebral artery. The incidence and significance of this sign are quantitatively evaluated in 50 patients entered into experimental drug studies for treatment of cerebral infarction.

High-dose intravenous naloxone for the treatment of acute ischemic stroke.

To evaluate the safety and possible efficacy of high-dose naloxone for the treatment of acute cerebral ischemia, 38 patients received a loading dose of 160 mg/m2 over 15 minutes followed by a 24-hour infusion at the rate of 80 mg/m2/hr. Nausea and/or vomiting were common side effects. Naloxone was discontinued in seven patients (because of hypotension in one, bradycardia and hypotension in two, myoclonus in one, focal seizures in two, and hypertension in one); all seven patients responded to treatment and no permanent sequelae to naloxone were noted. Twelve of the 38 patients showed early neurologic improvement (by completion of the naloxone loading dose). However, there was no correlation between such a loading dose response and clinical outcome at 3 months. Our experience suggests that naloxone is safe at the dose used, but data for efficacy are inconclusive.

Early treatment for acute ischemic stroke

Excerpt Early treatment for ischemic stroke has been a difficult objective to attain and has been stated to be impractical for several reasons. Stroke patients, who usually have no pain and may not...

Use of ancrod in acute or progressing ischemic cerebral infarction

Ancrod has been used in Europe for over 15 years for peripheral vascular disease, deep vein thrombosis, and central retinal venous thrombosis, and in patients at risk for thromboembolism. In a double-blind, randomized, placebo-controlled study at University Hospitals in Cincinnati, 20 acute cerebral infarction patients received a series of IV infusions of ancrod (ten) or placebo (ten) for seven days. Early fibrinolysis with a small decrease in fibrinogen was observed, and d-dimers were elevated at four hours, indicating early clot lysis. At three months, patients with moderate to severe strokes (less than 40 on the Scandinavian Stroke Scale) in the ancrod group showed average improvement by a factor of 3 over the placebo group. No bleeding, abnormal laboratory results, or deaths occurred, but ancrod was discontinued in one patient who had seizures. As a result of this study, a double-blind multicenter international clinical trial to further assess the safety and effectiveness of ancrod is being planned.

Ancrod Causes Rapid Thrombolysis in Patients with Acute Stroke

Clot lysis is desirable in patients with thrombi in arteries and arterioles by a safe rapidly-acting thrombolytic agent. Ancrod cleaves fibrinogen; the resulting circulating ancrod-fibrin stimulates fibrinolysis. Ancrod action and effect were studied in 20 patients with acute developing stroke in a double-blind, placebo-controlled study. Patients were randomly assigned to one of two treatment groups, and received either normal saline or ancrod 0.5 mu/kg in normal saline administered as a constant-rate intravenous infusion over 6 hours. Subsequent doses of ancrod (or saline placebo) were determined daily thereafter for a total treatment period of 7 days. Neither bleeding nor re-thrombosis occurred within the 90 day follow-up period. That ancrod acted rapidly was shown by a significant decrease in functional plasminogen activator inhibitor (PA-I) within 60 minutes, and by significant elevations of fibrin(ogen) degradation products (FDP) and D-dimer within 3 and 4 hours. The biological effect of fibrinolysis in ancrod infused patients was demonstrated by a greater improvement in stroke score when compared to those infused with saline.

Identification and entry of the patient with acute cerebral infarction.

Although time has been recognized as a critical factor in the treatment of other arterial occlusive disorders, it has been an underemphasized variable in the treatment of acute stroke. Animal models of cerebral arterial occlusion have demonstrated that neurologic recovery is more likely the shorter the duration of occlusion. Complete recovery does not occur if the occlusion persists more than six hours. Prior trials have only rarely begun treatment within six hours of stroke onset. Over the past five years, we have participated in three stroke trials and have tried to identify factors that lead to delays in treatment. Factors that affect the time from stroke onset to arrival at the hospital include recognition of acute stroke by the patient, prehospital care personnel, and physicians. After arrival at the hospital, factors that can significantly delay treatment include the time to obtain computed tomography and the site of treatment (emergency department vs ICU). With proper attention, the time from patient arrival until treatment should be less than one hour. Future efforts should be directed toward reducing the time from stroke onset until arrival at the hospital. Education of the public, high-risk patients, prehospital care providers, and physicians may aid in these efforts.

Use of high dose naloxone in acute stroke: Possible side-effects

The effects of high dose naloxone in humans have not been studied extensively. We treated 36 patients who had acute ischemic cerebral infarction with high doses of naloxone to evaluate potential efficacy and toxicity. All patients were treated with a 160-mg/m2 (4-mg/kg) loading dose followed by 80 mg/m2.h (2 mg/kg.h) x 24 h. There were no statistically significant changes in group mean arterial pressure, respiratory rate, or heart rate in response to the loading dose or infusion, although clinically significant changes did occur in four patients. Twenty-three patients had adverse reactions possibly related to naloxone, the most common of which were nausea (n = 20), bradycardia and/or hypotension (n = 3), myoclonus (n = 1), and hypertension (n = 1). Seven patients had naloxone discontinued for possible adverse reactions. All adverse reactions abated with discontinuation of naloxone and/or pharmacologic therapy when indicated. No deaths were attributable to naloxone treatment. High dose naloxone appears to be well tolerated in the majority of elderly patients with acute cerebral infarction.

Comparison of admission serum glucose concentration with neurologic outcome in acute cerebral infarction. A study in patients given naloxone

We studied the ability of serum glucose concentration and neurologic deficits at admission in predicting the outcome of acute cerebral ischemia in 65 patients given naloxone. Among our patients, the volume of infarction on computed tomograms and outcome were strongly related to the severity of neurologic deficits found at admission. Neither a history of diabetes nor hyperglycemia when added to the results of the initial neurologic assessment improved prediction of outcome after acute cerebral infarction.

The Investigational Use of tPA for Stroke

Stroke therapy trials have historically allowed for late patient entry (ie, within 24 to 48 hours from stroke onset) despite evidence suggesting the importance of early intervention. Experimental studies of cerebral infarction suggest treatment may be most effective when begun within three hours and may be only marginally effective when begun after 12 hours. Lysis of an acute intra-arterial thrombus in the setting of thrombolytic therapy is also time dependent. We describe an ongoing dose-escalation study of tissue plasminogen activator (tPA) as ultra-early therapy for cerebral infarction. The protocol requires that hemorrhage be ruled out by computed tomography scan of the brain prior to tPA infusion, and the infusion must begin within 90 minutes of symptom onset. The two primary goals of the study are to assess safety and potential efficacy. Preliminary results from the study and the future of ultra-early stroke intervention are discussed.