Rebound intracranial hypertension in dogs after resuscitation with hypertonic solutions from hemorrhagic shock accompanied by an intracranial mass lesion.

We compared intracranial pressure (ICP) and cerebral blood flow (CBF) in dogs after inflating a subdural intracranial balloon to increase ICP to 20 mm Hg, inducing hemorrhagic shock (mean arterial pressure [MAP] of 55 mm Hg), and infusing a single bolus of fluid consisting of either 54 mL/kg of 0.8% saline (SAL), 6 mL/kg of 7.2% hypertonic saline (HS), 20% hydroxyethyl starch (HES) in 0.8% SAL, or a combination fluid (HS/HES) containing 20% HES in 7.2% saline. Twenty-six dogs were ventilated with 0.5% halothane in N2O and O2 (60:40 ratio). As ICP was maintained at 20 mm Hg, rapid hemorrhage reduced MAP to 55 mm Hg (time interval of zero [T0]) which was maintained at that level for 30 minutes (until T30). Subsequently, over a 5-minute interval (T30-T35), one of the four randomly assigned resuscitation fluids was infused. Data were collected at baseline; after subdural balloon inflation; at T0, T30, T35, and 30-minute intervals thereafter for 2 hours (T65, T95, T125, and T155). CBF and ICP were compared using repeat-measure ANOVA. Cerebral blood flow was greater at T35 in the HS and HS/HES groups than in the HES group (P = .025). In the SAL group, ICP increased significantly from T0 to T35, remaining unchanged thereafter. At T35, ICP in the HS group was significantly lower than in the SAL group (P < .05) but subsequently increased. ICP in the HS/HES group exceeded that in all other groups at T95 and T125 (P < .05). After a severe reduction in cerebral perfusion pressure (CPP), HS solutions (both HS and HS/HES) were associated with a delayed rise in ICP and did not improve global forebrain CBF in comparison with conventional saline solutions.

Lymphangiolipoma of the thoracic spine in a pediatric patient with Proteus syndrome.

Proteus syndrome is a rare hamartomatous disorder involving macrodactyly, hemihypertrophy, and subcutaneous lymphangiomas; fewer than 25 cases have been reported worldwide. We report a case of a thoracic epidural lymphangiolipoma in a 5-year-old boy with Proteus syndrome. Computerized axial tomography (CT) of the thoracic spine revealed a left posterior mediastinal mass that extended into the spinal canal through adjacent neural foramina. No sign of spinal cord compression was observed despite the extensive volume of tumor within the spinal canal. Surgical debulking utilizing a T3-10 laminectomy resulted in gross total resection of the tumor. Microscopic examination of the surgical specimen revealed a lymphangiolipoma. No previous report of spinal cord involvement has been reported in this syndrome. A detailed discussion of the phenotypic features and probable mode of genetic transmission is included.

Carpal tunnel syndrome. A guide to prompt intervention.

Carpal tunnel syndrome is the most common entrapment neuropathy in the United States. The diagnosis should be considered for any patient with hand or wrist pain, weakness, or numbness. Changes in sensory conduction velocities across the wrist appear to be the most sensitive electrophysiologic indicators of the condition. Treatment of mild cases involves avoiding the precipitating activity, wrist splinting, and local steroid injections; surgical decompression is often required for moderate and severe cases. Overall, prognosis relates directly to the severity of the median nerve injury at diagnosis, the clinical cause, and the mode of treatment.

Regional cerebrovascular responses to progressive hypotension after traumatic brain injury in cats.

We investigated the effects of hypotension on cerebral blood flow (CBF) after traumatic brain injury (TBI) in cats. Isoflurane-anesthetized cats were prepared for TBI and for microsphere measurements of total (T) and regional (r) CBF. Four groups were studied: sham injury (group I, n = 6); TBI (group II, n = 6); isoflurane anesthesia, no TBI or hypotension (group III, n = 4); and isoflurane and TBI, no hypotension (group IV, n = 8). After TBI or sham trauma, mean arterial pressure (MAP) was reduced to 80, 60, and 40 mmHg by hemorrhage. Group I TCBF did not change significantly from baseline until MAP reached 40 mmHg, but rCBF was more dependent on MAP in anterior hemispheric than in brain stem regions. Group II TCBF was significantly lower than baseline, and group I TCBF at all levels of hypotension and autoregulation was impaired at higher MAP levels in anterior than in posterior brain regions. Groups III and IV indicated that decreases in TCBF were not due to duration of the preparation or to TBI in the absence of hemorrhagic hypotension. We conclude that global and regional autoregulation are absent in response to hemorrhagic hypotension after TBI.

Reduced cerebral blood flow, oxygen delivery, and electroencephalographic activity after traumatic brain injury and mild hemorrhage in cats.

The authors investigated the effects of transient, mild hemorrhagic hypotension after fluid-percussion traumatic brain injury on intracranial pressure, cerebral blood flow (CBF), cerebral oxygen delivery (CBF x arterial O2 content), and electroencephalographic (EEG) activity. Adult mongrel cats were anesthetized with 1.6% isoflurane in N2O:O2 (70:30) and prepared for trauma and for radioactive microsphere CBF measurement. Isoflurane concentration was decreased to 0.8%, and the cats were randomly assigned to one of four control groups or to an experimental group. Animals in the four control groups underwent either mild hemorrhage (18 ml.kg-1) immediately followed by resuscitation with equal volumes of 10% Hetastarch (eight cats), mild hemorrhage followed by replacement of shed blood (six cats), isovolemic hemodilution with 18 ml.kg-1 of Hetastarch (six cats), or moderate (2.2 atm) trauma alone (eight cats). The experimental group received a combination of trauma and mild hemorrhage followed by resuscitation with Hetastarch (eight cats). Mild hemorrhage produced no significant changes in CBF, renal blood flow, or cardiac output. Following resuscitation from mild hemorrhage, mean arterial blood pressure, cardiac output, renal blood flow, and CBF were not significantly different from baseline; cardiac output and renal blood flow did not differ significantly from baseline 2 hours after Hetastarch resuscitation. Neither hemorrhage nor trauma alone produced significant decreases in CBF or in EEG activity, but trauma followed by hemorrhage and resuscitation produced significant (p less than 0.01) decreases in CBF, cerebral oxygen delivery, and EEG score. These data demonstrate that, following traumatic brain injury, even mild hemorrhagic hypotension is associated with significant deficits in cerebral oxygen availability and neurological function.

Hypertonic/hyperoncotic fluid resuscitation after hemorrhagic shock in dogs.

We compared canine systemic and cerebral hemodynamics after resuscitation from hemorrhagic shock with 4 mL/kg (a volume approximating 12% of shed blood volume) of 7.2% saline (HS; 1233 mEq/L sodium), 20% hydroxyethyl starch (HES) in 0.8% saline, or a combination fluid consisting of 20% hydroxyethyl starch in 7.2% saline (HS/HES). Eighteen endotracheally intubated mongrel dogs (18-24 kg) were ventilated to maintain normocarbia with 0.5% halothane in nitrous oxide and oxygen (60:40). After a 30-min period of hemorrhagic shock (mean arterial blood pressure = 40 mm Hg), extending from time T0 to T30, animals received one of three randomly assigned intravenous resuscitation fluids: HS, HES, or HS/HES. Data were collected at baseline, at the beginning and end of the shock period (T0 and T30), immediately after fluid infusion (T35), and at 60-min intervals for 2 h (T95, T155). After resuscitation, mean arterial blood pressure and cardiac output increased similarly in all groups, but failed to return to baseline. Intracranial pressure decreased during shock and increased slightly, immediately after resuscitation in all groups. During shock, cerebral blood flow (cerebral venous outflow method) declined in all groups. After resuscitation, cerebral blood flow increased, exceeding baseline in the HS and HS/HES groups but remaining low in the HES group (P less than 0.05 HS vs HES at T35). We conclude that small-volume resuscitation (4 mL/kg) with HS, HS/HES, or HES does not effectively restore or sustain systemic hemodynamics in hemorrhaged dogs. In dogs without intracranial pathology, the effects on cerebral hemodynamics are also comparable, except for transiently greater cerebral blood flow in the HS group in comparison with the HES group.

Cerebral hemodynamic effects of fluid resuscitation in the presence of an experimental intracranial mass.

We addressed the impact on intracranial pressure (ICP) of posthemorrhage fluid resuscitation with a protocol in which additional fluid was infused to maintain a stable cardiac output after an initial bolus of fluid was infused. Anesthetized, mechanically ventilated mongrel dogs (n = 27) underwent a 30-minute interval of hemorrhagic shock (mean arterial pressure = 55 mm Hg) during which inflation of a subdural balloon maintained ICP at 15 mm Hg. After shock, animals were resuscitated with one of four randomly assigned fluids: (1) slightly hypotonic crystalloid (Na+, 125 mEq.L-1; designated Na-125); (2) hypertonic crystalloid (Na+, 250 mEq.L-1; designated Na-250); (3) slightly hypotonic crystalloid plus 10% pentastarch (Na-125P); or (4) hypertonic crystalloid plus 10% pentastarch (Na-250P). Supplemental fluid was administered as needed to maintain cardiac output comparable to baseline values. ICP increased progressively in all fluid groups during resuscitation. Cerebral blood flow, measured by the cerebral venous outflow method, increased immediately after resuscitation and then declined steadily over time in all groups. Fluids containing pentastarch maintained hemodynamic stability with minimal supplementation throughout most of the postresuscitation period, compared with crystalloid alone, which required substantial additional volume. If decreased intracranial compliance and hemorrhage are combined, ongoing resuscitation is associated with significantly increased ICP and significantly decreased cerebral blood flow, independent of the tonicity and oncotic pressure of the infused fluid.

Regional cerebral blood flow following resuscitation from hemorrhagic shock with hypertonic saline. Influence of a subdural mass.

After severe hemorrhage, hypertonic saline restores systemic hemodynamics and decreases intracranial pressure (ICP), but its effects on regional cerebral blood flow (rCBF) when used for resuscitation of experimental animals with combined shock and intracranial hypertension have not been reported. We compared rCBF changes (by radiolabeled microsphere technique) after resuscitation from hemorrhage with either 0.8 or 7.2% saline in animals with and without a right hemispheric subdural mass. We studied 24 mongrel dogs anesthetized with 0.5% halothane and 60% nitrous oxide. In group 1 (n = 12), hemorrhage reduced mean arterial pressure (MAP) to 45 mmHg for 30 min. In group 2 (n = 12), ICP was increased and maintained constant at 15 mmHg, whereas hemorrhage reduced MAP to 55 mmHg for 30 min (cerebral perfusion pressure [CPP] approximately 40 mmHg in each group). After the 30-min shock period, 6 animals in each group received one of two randomly assigned resuscitation fluids over a 5-min interval: 1) 7.2% hypertonic saline (HS; sodium 1,232 mEq.l-1, volume 6.0 ml.kg-1); or 2) 0.8% isotonic saline (SAL; sodium 137 mEq.l-1, volume 54 ml.kg-1). Once fluid resuscitation began, ICP was permitted to vary independently in both groups. Data were collected at baseline (before subdural balloon inflation in group 2), midway through the shock interval (T15), immediately after fluid infusion (T35), and 60 and 90 min later (T95, T155). In groups 1 and 2, ICP was significantly less in animals resuscitated with HS compared to those receiving SAL (P less than 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)

Hemorrhage and intracranial hypertension in combination increase cerebral production of thromboxane A2.

BACKGROUND AND METHODS: To determine the effects of reduced cerebral perfusion pressures produced by hemorrhage alone or in combination with intracranial hypertension on thromboxane A2 (TxA2) production, we undertook a randomized study in 38 anesthetized, mongrel dogs. Animals were subjected to 30 mins of hemorrhagic shock with normal (group 1) or increased (group 2) intracranial pressure (ICP). Group 1 animals (n = 22) were hemorrhaged to reduce cerebral perfusion pressure to 40 mm Hg for 30 mins. In group 2 (n = 16), cerebral perfusion pressure was reduced by the combination of less severe hypotension and intracranial hypertension (20 mm Hg). Cerebral and systemic hemodynamic measurements were recorded, including cerebral blood flow (sagittal sinus outflow method); ICP; cerebral perfusion pressure; and arterial and cerebral venous concentrations of TxB2 (double-antibody radioimmunoassay technique), the major metabolite of TxA2. Data were obtained at baseline and at the beginning and end of the 30-min shock period. RESULTS: Hemorrhagic shock significantly (p less than .05) decreased cerebral blood flow in both groups. At the beginning of the shock period, cerebral blood flow was higher in group 1 than in group 2 (p less than .05) and venous-arterial differences in TxB2 increased significantly (p less than .05) in group 2, but not in group 1. At the end of the 30-min shock period, venous-arterial levels of TxB2 remained significantly (p less than .05) higher in group 2. CONCLUSIONS: Increased cerebral production of TxA2 during hypotension accompanied by intracranial hypertension may contribute to the severity of neural damage produced by the combination of head trauma and shock.

Cerebrovascular effects of small volume resuscitation from hemorrhagic shock: comparison of hypertonic saline and concentrated hydroxyethyl starch in dogs.

To determine if hypertonic and hyperoncotic resuscitation solutions exerted comparable effects on cerebral hemodynamics following hemorrhagic shock, we compared randomly assigned, equal volumes (6.0 ml/kg) of hypertonic (7.2%) saline (HS) and hyperoncotic (20%) hydroxyethyl starch (HES) for resuscitation from acute experimental hemorrhage in 12 anesthetized dogs. Regional cerebral blood flow (radiolabeled microspheres), intracranial pressure (cisternal catheter), and systemic hemodynamics were recorded. Rapid hemorrhage reduced the mean arterial pressure to 45 mm Hg for 30 min. Resuscitation fluids were infused over 5 min. Both fluids restored mean arterial pressure and cardiac output equally. However, at 60 min following resuscitation, cardiac output decreased in the HS group in comparison to the HES group (1.7 +/- 0.1 vs. 3.1 +/- 0.2 L/min, p <0.05). Cardiac output rapidly declined, however, in the HS group in comparison to the HES group (p <0.05 60 min following resuscitation). Intracranial pressure and cerebral perfusion pressure were similar at all intervals. Regional cerebral blood flow was similar following both fluids. Neither fluid restored cerebral oxygen transport to baseline values. Based on these data, the authors conclude that, following severe hemorrhagic shock of brief duration, systemic and cerebral hemodynamic values are restored equally well by highly concentrated colloid or by hypertonic saline, although hypertonic saline only transiently improves cardiac output.

Small-volume resuscitation from hemorrhagic shock in dogs: effects on systemic hemodynamics and systemic blood flow.

BACKGROUND AND METHODS: This study compared canine systemic hemodynamics and organ blood flow (radioactive microsphere technique) after resuscitation with 0.8% saline (Na+ 137 mEq/L), 7.2% hypertonic saline (Na+ 1233 mEq/L), 20% hydroxyethyl starch in 0.8% saline, or 20% hydroxyethyl starch in 7.2% saline, each in a volume approximating 15% of shed blood volume. Twenty-four endotracheally intubated mongrel dogs (18 to 24 kg) underwent a 30-min period of hemorrhagic shock, from time 0 to 30 min into the shock period, followed by fluid resuscitation. Data were collected at baseline, 15 min into the shock period, immediately after fluid infusion, 5 min after the beginning of resuscitation, and at 60-min intervals for 2 hr, (65 min after the beginning of resuscitation, and 125 min after the beginning of resuscitation). The animals received one of four randomly assigned iv resuscitation fluids: saline (54 mL/kg), hypertonic saline (6.0 mL/kg), hydroxyethel starch (6.0 mL/kg) or hypertonic saline/hydroxyethyl starch (6.0 mL/kg). RESULTS: Mean arterial pressure increased in all groups after resuscitation. Cardiac output increased with resuscitation in all groups, exceeding baseline in the saline and hypertonic saline/hydroxyethyl starch groups (p less than .05 compared with hypertonic saline or hydroxyethyl starch). Sixty-five minutes after the beginning of resuscitation, cardiac output was significantly (p less than .05) greater in either of the two colloid-containing groups than in the hypertonic saline group. After resuscitation, hypertonic saline and hydroxyethyl starch produced minimal improvements in hepatic arterial flow, hypertonic saline/hydroxyethyl starch increased hepatic arterial flow to near baseline levels, and saline markedly increased hepatic arterial flow to levels exceeding baseline (p less than .05, saline vs. hydroxyethyl starch). One hundred twenty-five minutes after the beginning of resuscitation, hepatic arterial flow had decreased in all groups; hepatic arterial flow in the hypertonic saline group had decreased to levels comparable with those during shock. Myocardial, renal, and brain blood flow were not significantly different between groups. CONCLUSIONS: Small-volume resuscitation with the combination of hypertonic saline/hydroxyethyl starch is comparable with much larger volumes of 0.8% saline, and is equal to hypertonic saline or hydroxyethyl starch in the ability to restore and sustain BP and improve organ blood flow after resuscitation from hemorrhagic shock.

Thromboxane A2 receptor antagonist SQ29548 does not improve canine postischemic cerebral hypoperfusion.

The thromboxane receptor antagonist SQ29548 was administered to mongrel dogs after an 11-min period of global cerebral ischemia to test the hypothesis that it would improve delayed postischemic cerebral hypoperfusion (PIH) during concurrent elevations in cerebral venous thromboxane B2 (TxB2), the stable metabolite of thromboxane A2 (TxA2). Immediately following an 11-min period of aortic root cross-clamping, six dogs received 0.2 mg/kg of SQ29548 intravenously followed by continuous infusion of 0.2 mg/kg/h (TRA group) and six received a saline placebo (control). Over the next 120 min, cerebral venous outflow was measured from the confluence of the sagittal and lateral sinuses, while arterial and cerebral venous samples were obtained for measurement of TxB2. Delayed postischemic cerebral hypoperfusion, confirmed in the control group (p < 0.05) (16 +/- 2.7 vs. 32 +/- 2.4 ml/min baseline), was nearly identical in the TRA group (14 +/- 0.9 vs. 30 +/- 2.5 ml/min baseline). Cerebral venous TxB2 levels rose dramatically in both groups after ischemia (3670 +/- 440 vs. 1100 +/- 350 pg/ml baseline, control and 2720 +/- 170 vs. 580 +/- 100 pg/ml baseline, TRA group) (p < 0.05). There were no significant group mean differences in any of the other hemodynamic data except mean arterial pressure (MAP) at T120 and Hgb at baseline. We conclude that postischemic intravenous administration of the thromboxane receptor-specific antagonist SQ29548 fails to improve delayed postischemic cerebral hypoperfusion and does not alter cerebral venous TxB2 release in this canine model of global cerebral ischemia.

Ibuprofen improves cerebral blood flow after global cerebral ischemia in dogs.

In a canine model of global cerebral ischemia, 6 dogs received a saline placebo prior to the event and 5 received 12.5 mg/kg ibuprofen. Cerebral venous outflow from the confluence of the sagittal and transverse sinuses, systolic and diastolic arterial pressure, cardiac output, pH, Paco2, Pao2, and arterial and sagittal sinus thromboxane B2 and 6-keto-PGF1 alpha were measured at intervals up to 120 minutes thereafter. Postischemic cerebral hypoperfusion was significantly improved in the ibuprofen pretreatment group. Control dogs showed significant increases in sagittal sinus postischemic thromboxane B2 concentrations, but pretreated dogs showed nearly complete inhibition of postischemic thromboxane B2 production. Pretreated dogs also had significantly lower levels of 6-keto-PGF1 alpha from the sagittal sinus. There were no significant differences in the other variables at any interval. We conclude that ibuprofen ameliorates postischemic cerebral hypoperfusion, and that this improvement is associated with decreased sagittal sinus levels of thromboxane B2 and 6-keto-PGF1 alpha.

Topographical organization of the inferior collicular projection and other connections of the ventral nucleus of the lateral lemniscus in the cat.

The topographic distribution of projections from the ventral nucleus of the lateral lemniscus (VNLL) in the cat was investigated with the autoradiographic tracing method. The origin of minor projections was verified by retrograde tracing methods. Small injections of tritiated leucine were placed in restricted zones of VNLL. A major afferent fiber system to the inferior colliculus was labeled in all cases. From the injection site labeled fibers coursed through and around the nuclei of the lateral lemniscus to enter the ipsilateral inferior colliculus. Regardless of the position or small size of the injection, labeled fibers distributed widely in the inferior colliculus. Fibers ended in the central nucleus and deeper layers of the dorsal cortex in most cases. There was also labeling in the ventrolateral nucleus, but very few fibers ended as lateral as the lateral nucleus. A small number of labeled fibers passed from the inferior colliculus into the nucleus of the brachium of the inferior colliculus and adjacent tegmental areas. Some labeled fibers entered the commissure of the inferior colliculus where they were traced into the dorsal cortex and rostral pole of the inferior colliculus on the side contralateral to the injection site. Though the projections labeled in individual cases were similar in their divergent pattern within the central nucleus of the inferior colliculus, specific variations in the pattern were found. The dorsal zone of VNLL projected more heavily to the deeper layers of the dorsal cortex and an adjacent field in the central nucleus than the other zones. Dorsal injections in the middle zone of VNLL, on the other hand, labeled the medial part of the central nucleus more heavily, whereas ventral injections in the middle zone resulted in heavier lateral labeling. The ventral zone of VNLL projected heavily to a central field in the central nucleus. In addition to this major afferent system of VNLL to the inferior colliculus, a smaller descending projection was found. The descending projection ended mainly in the dorsomedial periolivary region and ventral nucleus of the trapezoid body. However, in some cases a few fibers were traced to the cochlear nuclei. Finally, we observed projections to the medial geniculate body from the dorsal and ventral zones of VNLL that ended diffusely in the medial division of the medial geniculate body. Possibly some fibers from the dorsal zone contribute to a broader projection of the lateral tegmentum to the dorsal division of the medial geniculate body.