Carotid artery pseudoaneurysm and pellet embolism to the middle cerebral artery following a shotgun wound of the neck.

Arterial missile embolism is a rare complication of penetrating vascular trauma. We report a case of middle cerebral artery pellet embolism and delayed appearance of a carotid artery pseudoaneurysm following a shotgun wound of the neck. The pseudoaneurysm was repaired. Because the patient had no associated neurologic deficits, the pellet embolus was left within the patient middle cerebral artery. He remains well 4 years after injury. A selective approach to the management of a pellet embolus to the middle cerebral artery based on clinical signs or symptoms and status of arterial patency is recommended. In addition, several principles are suggested to improve the reliability of arteriography for shotgun wounds of the neck.

Inhalation regional cerebral blood flow: the use of tidal CO2 data to find radionuclide activity associated with exhaled alveolar gas.

When calculating cerebral blood flow by the inhalation regional cerebral blood flow technique, radionuclide activity associated with exhaled alveolar gas is used to represent the arterial input function for each brain region. In this study, tidal CO2 data are used to identify respiratory gas samples that contain alveolar gas. Traditional methods identify alveolar gas samples by searching for maxima and minima in the raw air curve. The raw air curve is determined by sequentially counting radionuclide activity in respiratory gases sampled at the mouth. Traditional methods sometimes erroneously identify and use maxima or minima that do not represent alveolar gas. The use of CO2 data is advantageous since the range of CO2 during exhalation can identify those exhalations that approach the functional reserve capacity and hence represent alveolar gas. The arterial input function is represented by counting intervals from the raw air curve which coincide with exhalation of alveolar gas as identified by CO2 data. This approach for representing the arterial input function is fully automatic, accurate, and reproducible.

The rCBF response to Diamox in normal subjects and cerebrovascular disease patients.

Age-related norms for the regional cerebral blood flow (rCBF) response to Diamox (acetazolamide) were based on studies of 55 normal subjects at rest and on studies of 33 of these 55 normal subjects following an intravenous injection of Diamox (22 mg/kg). After the Diamox injection, rCBF increased at all locations measured in all subjects. On average, rCBF increased 1.7 times. The following were found for rCBF in both resting and Diamox-treated subjects: 1) rCBF decreased significantly with increasing age; 2) slope and intercept for the regression of rCBF on age were largest for frontal detectors, intermediate for parietal detectors, and smallest for occipital detectors; 3) rCBF hyperfrontality was most noticeable in younger subjects; 4) in subjects of any age, 95% confidence intervals for rCBF were relatively large (expected value +/- 30%) and lower 95% confidence intervals for Diamox rCBF tended to overlap the upper 95% confidence intervals for resting rCBF; and 5) side-to-side percentage difference in rCBF did not have a significant regression on age and tended to be less than 10% to 20%. Diamox did not have an important effect on blood pressure, pulse rate, or respiratory rate. The normative data for the rCBF response to Diamox was used in evaluating 20 patients with cerebrovascular disease. Forty percent of these patients, all of whom exhibited angiographic evidence of potentially hemodynamically significant lesions, had normal rCBF at rest and after Diamox injection. Twenty percent had normal resting flows with abnormal Diamox-activated flows. Asymmetry in rCBF was the most sensitive indicator of a potential abnormality in cerebral perfusion. Thirty percent of the abnormal studies showed only significant asymmetry. It is suggested that rCBF studies at rest and after Diamox treatment, with age-related norms, may be useful in the management of patients with cerebrovascular disease.

Analysis of inhalation rCBF data.

Relative to other approaches that have been recommended, fitting all head data, solving for a time shift, and including an air passage artifact term in the model significantly improved the estimate of gray matter blood flow by the inhalation technique. A robust algorithm, which incorporates these features, has been developed. Formulas which facilitate implementation of this algorithm are reported. An artifact from large scalp arteries was not significant and does not need to be included in the model.

Acute anterior spinal epidural abscess.

We have reported a case of acute spinal epidural abscess, an uncommon cause of pain in the neck and back. The typical progression from spinal ache to paralysis may be halted if the diagnosis is suspected and prompt radiologic and surgical interventions are initiated.

Improvements in the technique of spinal subarachnoid recirculatory perfusion.

With 14C-labeled dextran as the tracer, studies of the original configuration of spinal recirculatory perfusion and the original model for data analysis demonstrated that this approach does not yield acceptable accuracy in determining cerebrospinal fluid (CSF) formation (Fcsf) and absorption (Acsf) rates. A significant component of this error was due to the fact that the method of data analysis used originally is not based on a realistic mathematical model of the system. A more realistic mathematical model resulted in two simultaneous differential equations that did not have simple analytical solutions and, therefore, could not be used easily for data analysis. By computer simulation, a comparison of the more realistic model with the original model demonstrated that, under ideal conditions, there was a 10% error inherent in the original data analysis method. In the experimental setting, the magnitude of this inherent error is probably 20%. There were three other major problems with the original system: (a) one could not tell when enough data had been collected to ensure convergence of the data analysis algorithm; (b) calibration of the syringe pump in the external circuit was not accurate for short infusion periods; and (c) the presence of the syringe in the external circuit unnecessarily lengthened the period of nonhomogeneous mixing. A new system configuration and new data analysis methods have been developed. In the new system, the syringe is removed from the external circuit and intracranial pressure is controlled by infusion from a separate reservoir where the pressure head is maintained at any desired level by feedback control. Spectrophotometry is used to measure tracer concentration in the external circuit. Data collection and analysis are fully automated under computer control so that, during an experimental run, the investigators are updated at 1- to 2-second intervals as to the convergence of the data analysis routine. Data analysis methods for the new system are superior to previous methods because the models are realistic and no extrapolation is required. In addition, all of the data during the initial period of nonhomogeneous mixing are used to calculate Fcsf and Acsf. With the new system and a simple phantom of the CSF system, the mean error in finding Acsf was 1.7 +/- 1.2% for 27 determinations covering a wide range of absorption rates. Fcsf could be determined to within 0.001 ml/minute. In up to six sequential pressure plateaus, the magnitude of error did not increase with each subsequent run.(ABSTRACT TRUNCATED AT 400 WORDS)

Interhemispheric subdural hematoma.

We have reported a case of primary interhemispheric subdural hematoma with successful surgical removal. Paresis of the lower extremity out of proportion to the arm and face may provide a clue to the location of the lesion. Although CT is the most valuable single diagnostic procedure, carotid angiography is needed to exclude a vascular lesion.

Effect of pressure on cerebrospinal fluid absorption in cats, baboons, and humans: comparison of the linear and logarithmic models.

To circumvent time constraints inherent in indicator clearance measurements of cerebrospinal fluid absorption, investigators have used the relationship between CSF pressure at steady state and the rate of infusion of mock CSF, in both patients and experimental animals, to evaluate the bulk absorption rate of CSF. This latter approach required mathematical model of the effect of CSF pressure on CSF bulk flow. Two such models--a fixed resistance and a variable resistance model of CSF flow through arachnoid villi--have been used in both clinical and laboratory settings. In this study, the relationship between steady state CSF pressure and mock CSF infusion rate was assessed using both mathematical models. We studied two patients, three cats, and seven baboons. Values of CSF outflow resistance calculated according to both models as well as other parameters of CSF bulk flow estimated on the basis of both models were all in the range expected from other studies. The data from these experiments do not provide justification for preferring one model over the other. Depending on the experimental or clinical situation, some of the assumptions behind both models may not be valid. Multiple direct measurements of the rates of CSF absorption and formation over a wide range of CSF pressures in individual subjects will be necessary to validate either the variable or the fixed resistance model or to suggest a more appropriate model. Until such information is available, it is probably reasonable to use both approaches for the analysis of mock CSF infusion data. CSF bulk flow parameters calculated on the basis of either the variable or the fixed resistance model should never be taken as absolute, but should be evaluated critically in the context of the clinical or experimental situation.

The critical importance of PaCO2 during intracranial aneurysm surgery. Case report.

In a patient undergoing craniotomy for clipping of an anterior communicating artery aneurysm, sodium nitroprusside was used to lower systemic arterial blood pressure to 80/35 mm Hg (mean arterial blood pressure (MABP) = 50 mm Hg), at which time the electroencephalogram (EEG) changed abruptly from normal to a burst suppression pattern. At the onset of burst suppression, PaCO2 was 18 mm Hg. After PaCO2 had been increased to 28 mm Hg, the patient tolerated a blood pressure of 45/25 mm Hg (MABP = 32 mm Hg) during aneurysm clipping without EEG change. The observations reported here support the conclusion that, with moderate hypotension, hypocarbia may cause brain ischemia and that the level of PaCO2 may influence the degree of hypotension that may be safely used during aneurysm surgery. The importance of repeated arterial blood gas measurements when induced hypotension is employed for berry aneurysm surgery is stressed. Intraoperative EEG monitoring may be employed to help judge safe levels of intraoperative hypotension during intracranial aneurysm surgery.

The CSF pressure-volume relationship before and after cardiac arrest in the cat.

The CSF pressure-volume (P-V) function was evaluated before and after cardiac arrest in 15 cats. The CSF volume change was produced by bolus loading (loading rate, greater than 0.1 mL/s) of the CSF space. Comparison of the CSF P-V function before and after cardiac arrest was made over a CSF pressure range of 5 to 46 mm Hg and for a CSF volume change of up to 9% of total CSF volume. After cardiac arrest, all CSF P-V curves were well described by the mathematical model konwn to be valid under normal physiological conditions. In eight animals, there was no significant difference between the prearrest and postarrest P-V functions. For the seven animals demonstrating a significant difference between prearrest and postarrest P-V data, all but one of the postarrest P-V curves were within the normal range. These results suggest that the shape of the CSF P-V curve is not substantially altered by cardiac arrest. We conclude that under normal circumstances material properties of brain tissue are the most important factors in determining the configuration of the CSF P-V curve and that under normal circumstances cerebral hemodynamic factors do not affect the shape of this curve.

Surgical removal of bilateral papillomas of the choroid plexus of the lateral ventricles with resolution of hydrocephalus. Case report.

The authors report a patient with bilateral papillomas of the choroid plexus of the lateral ventricles with documentation of cerebrospinal fluid (CSF) hypersecretion causing hydrocephalus. Special attention is given to the large volume of CSF produced by these tumors (removal of one tumor reduced CSF outflow by one-half) and to the fact that CSF diversion was not required after both tumors were removed. Since tumor removal alone was sufficient to stop the progression of hydrocephalus, we feel that this case supports the concept that elevated CSF production by itself is sufficient to cause hydrocephalus in patients with papillomas of the choroid plexus.

Bolous versus steady-state infusion for determination of CSF outflow resistance.

For rapid changes in cerebrospinal fluid volume an exponential relationship was demonstrated between CSF pressure and CSF volume in 15 cats. This relationship was valid over a CSF pressure range from 7 to 50 mm Hg and for acute increases of up to 9% to total CSF volume (approximately 13 ml for humans). Our data agree well with previous reports for the cat. A similar relationship has been shown in the dog and in humans. It has been claimed that, given the equations for CSF bulk flow and the exponential relationship between CSF pressure and CSF volume, one can calculate CSF outflow resistance by observing the decay of CSF pressure after a bolus injection into the CSF space. This claim was evaluated in an additional 18 cats. In these animals CSF outflow resistance calculated by the bolus method was compared with resistance calculated by a steady-state infusion method over the CSF outflow resistance range of 74 to 293 mm Hg/ml min-1. Resistance calculated by the bolus method underestimated resistance calculated by the steady-state method, and this underestimate grew larger with increasing resistance. The bolus technique is therefore not a valid method for determining CSF outflow resistance. The explanation offered for these results is that the decay of CSF pressure after a bolus injection into the CSF space occurs not only because of runoff of the injected volume of CSF but also because of "pressure relaxation" of the brain parenchyma around the CSF space. The phenomenon of pressure relaxation was not considered in developing the equation for calculation of CSF outflow resistance by the bolus technique. The time dependency of pressure relaxation allows for a fundamental element of hysteresis within the CSF space. A method of quantifying this element of hysteresis is suggested.

Vascular permeability alterations to horseradish peroxidase in experimental brain injury.

Protein uptake and transport within the brain stem vasculature of mechanically brain injured cats was studied by means of both light and electron microscopy utilizing intravenously injected horseradish peroxidase as the protein tracer. In animals sustaining low grade head injuries not of sufficient intensity to elicit either microscopic, intraparenchymal hemorrhages or subtle, neuropathological responses, peroxidase extravasation was noted both in the vascular walls and in the surrounding parenchyma of the ventromedial aspect of the brain stem. At the ultrastructural level as early as 3 min after brain injury, occasional arterioles, venules and capillaries displayed peroxidase leakage. In serial sections large endothelial segments of these vessels revealed the peroxidase reaction product within numerous vesicles which often shared continuity with tubular and vacuolar profiles. Such vesicular activity apparently moved the peroxidase from the luminal surface to extrude it into the basal lamina. From the perivascular basal lamina, the reaction product flooded the interstices of the surrounding brain stem parenchyma where occasional neural, glial and pericytic elements incorporated the peroxidase within coated invaginations, vesicles, tubules and vacuoles. In that protein leakage was consistently observed despite the apparent integrity of both the endothelial tight junctions and their cell membranes, it is concluded that the vesicular transport of horseradish peroxidase across the endothelia of the brain stem vasculature represents a possible mechanism of blood-brain barrier dysfunction in mechanical brain injury.