Cerebrospinal fluid drainage in posthaemorrhagic ventricular dilatation leads to improvement in amplitude-integrated electroencephalographic activity.

AIM: Progressive posthaemorrhagic ventricular dilatation (PHVD) may induce abnormal amplitude-integrated electroencephalographic (aEEG) activity prior to clinical deterioration or significant cerebral ultrasound changes. These abnormalities might be ameliorated with cerebrospinal fluid (CSF) drainage. The aims of this study were to investigate the occurrence of aEEG-abnormalities with progressive PHVD in relation to clinical and cerebral ultrasound changes and to evaluate whether CSF drainage results in aEEG improvement. METHODS: aEEG and cerebral ultrasound scans were performed in 12 infants with PHVD, before and after CSF drainage, until normalization of aEEG occurred. RESULTS: aEEG was abnormal with progressive PHVD in all patients. Concurrently, 60% of the patients were clinically stable without deterioration in ultrasonographic cerebral abnormalities. Post drainage, continuous pattern was restored in all but one patient, whereas the frequency of discontinuous pattern decreased in nine patients and burst-suppression pattern decreased in all but one patient. Low-voltage pattern was only observed in one patient who suffered severe grade IV IVH and died one week after EVD placement. Sleep-wake cycling matured in 75%. CONCLUSION: These findings demonstrate the impact of CSF drainage on compromised aEEG-activity associated with PHVD. aEEG changes indicative of impaired cerebral function were apparent before clinical deterioration or major ultrasound changes. These changes were reversible with CSF drainage. aEEG should therefore be used in addition to clinical observation and ultrasound when monitoring PHVD.

Ventricular dilation and elevated aqueductal pulsations in a new experimental model of communicating hydrocephalus.

In communicating hydrocephalus (CH), explanations for the symptoms and clear-cut effective treatments remain elusive. Pulsatile flow through the cerebral aqueduct is often significantly elevated, but a clear link between abnormal pulsations and ventriculomegaly has yet to be identified. We sought to demonstrate measurement of pulsatile aqueductal flow of CSF in the rat, and to characterize the temporal changes in CSF pulsations in a new model of CH. Hydrocephalus was induced by injection of kaolin into the basal cisterns of adult rats (n = 18). Ventricular volume and aqueductal pulsations were measured on a 9.4 T MRI over a one month period. Half of the animals developed ventricular dilation, with increased ventricular volume and pulsations as early as one day post-induction, and marked chronic elevations compared to intact controls (volume: 130.15 +/- 83.21 microl vs. 15.52 +/- 2.00 microl; pulsations: 114.51 nl +/- 106.29 vs. 0.72 +/- 0.13 nl). Similar to the clinical presentation, the relationship between ventricular size and pulsations was quite variable. However, the pulsation time-course revealed two distinct sub-types of hydrocephalic animals: those with markedly elevated pulsations which persisted over time, and those with mildly elevated pulsations which returned to near normal levels after one week. These groups were associated with severe and mild ventriculomegaly respectively. Thus, aqueductal flow can be measured in the rat using high-field MRI and basal cistern-induced CH is associated with an immediate change in CSF pulsatility. At the same time, our results highlight the complex nature of aqueductal pulsation and its relationship to ventricular dilation.

New experimental model of acute aqueductal blockage in cats: effects on cerebrospinal fluid pressure and the size of brain ventricles.

It is generally assumed that cerebrospinal fluid (CSF) is secreted in the brain ventricles, and so after an acute blockage of the aqueduct of Sylvius an increase in the ventricular CSF pressure and dilation of isolated ventricles may be expected. We have tested this hypothesis in cats. After blocking the aqueduct, we measured the CSF pressure in both isolated ventricles and the cisterna magna, and performed radiographic monitoring of the cross-sectional area of the lateral ventricle. The complete aqueductal blockage was achieved by implanting a plastic cannula into the aqueduct of Sylvius through a small tunnel in the vermis of the cerebellum in the chloralose-anesthetized cats. After the reconstitution of the occipital bone, the CSF pressure was measured in the isolated ventricles via a plastic cannula implanted in the aqueduct of Sylvius and in the cisterna magna via a stainless steel cannula. During the following 2 h, the CSF pressures in the isolated ventricles and cisterna magna were identical to those in control conditions. We also monitored the ventricular cross-sectional area by means of radiography for 2 h after the aqueductal blockage and failed to observe any significant changes. When mock CSF was infused into isolated ventricles to imitate the CSF secretion, the gradient of pressure between the ventricle and cisterna magna developed, and disappeared as soon as the infusion was terminated. However, when mock CSF was infused into the cisterna magna at various rates, the resulting increased subarachnoid CSF pressure was accurately transmitted across the brain parenchyma into the CSF of isolated ventricles. The lack of the increase in the CSF pressure and ventricular dilation during 2 h of aqueductal blockage suggests that aqueductal obstruction by itself does not lead to development of hypertensive acute hydrocephalus in cats.

Caudal block complication in a patient with trisomy 13.

In this report we describe a complication of a caudal block in a 4-year-old child with trisomy 13. The patient's history was remarkable for microcephaly, developmental delay, seizures, apnea, and prolonged emergence times. Induction of anesthesia and tracheal intubation were uneventful. A caudal block was aborted after positive aspiration of cerebrospinal fluid. A radiogram suggestive of spinal dysraphism, found on subsequent review, was confirmed by a magnetic resonance imaging scan consistent with tethered cord and dural ectasia. Congenital abnormalities associated with trisomy 13 and cutaneous signs suggestive of spinal abnormalities are reviewed. Avoidance of neuraxial regional anesthesia in these patients is recommended.

Posthaemorrhagic ventricular dilatation: new mechanisms and new treatment.

Post haemorrhagic ventricular dilatation is associated with a high rate of disability, multiple impairments and adverse effects of shunt surgery for hydrocephalus. Post haemorrhagic ventricular dilatation results initially from multiple small blood clots throughout the cerebrospinal fluid channels impeding circulation and re-absorption. Transforming growth factor beta is released into the cerebrospinal fluid and there is evidence that this cytokine stimulates the laying down of extracellular matrix proteins which produce permanent obstruction to the cerebrospinal fluid pathways. Prolonged raised pressure, pro-inflammatory cytokines and free radical damage from iron may contribute to periventricular white matter damage and subsequent disability. Interventions such as early lumbar punctures, diuretic drugs to reduce cerebrospinal fluid production and intraventricular fibrinolytic therapy have been tested and, not only fail to prevent shunt dependence, death or disability, but have significant adverse effects. Surgical interventions such as subcutaneous reservoir, external drain, choroid plexus coagulation and third ventriculostomy have not been subject to controlled trial. Ventriculoperitoneal shunt is not feasible in the early phase after intraventricular haemorrhage but, despite the problems with blockages and infections, remains the only option for infants with excessive head expansion over periods of weeks. We have piloted drainage, irrigation and fibrinolytic therapy as a way of removing blood early enough to stop the progressive deposition of matrix proteins, permanent hydrocephalus and shunt dependence.

Frequency analyses of CSF flow on cine MRI in normal pressure hydrocephalus.

Our objective was to clarify intracranial cerebrospinal fluid (CSF) flow dynamics in normal-pressure hydrocephalus (NPH). Frequency analyses of CSF flow measured with phase-contrast cine MRI were performed. The CSF flow spectra in the aqueduct were determined in patients ( n=51) with NPH, brain atrophy or asymptomatic ventricular dilation (VD), and in healthy volunteers (control group; n=25). The changes in CSF flow spectra were also analyzed after intravenous injection of acetazolamide. Moreover, a phase transfer function (PTF) calculated from the spectra of the driving vascular pulsation and CSF flow in the aqueduct were assessed. These values were compared with the pressure volume response (PVR). The amplitude in the NPH group was significantly larger than that in the VD or control group because of a decrease in compliance. The phase in the NPH group was significantly different from that in either the VD or the control group, but no difference was found between the VD and control groups. The amplitude increased in all groups after acetazolamide injection. The PTF in the NPH group was significantly larger than in the control group, and a positive correlation was noted between PTF and PVR. Frequency analyses of CSF flow measured by cine MRI make it possible to noninvasively obtain a more detailed picture of the pathophysiology of NPH.

Elevation of transforming growth factor-beta 1 level in cerebrospinal fluid of patients with communicating hydrocephalus after subarachnoid hemorrhage.

BACKGROUND AND PURPOSE: Transforming growth factor-beta 1 (TGF-beta 1) is a multifunctional polypeptide that controls the production of extracellular matrix protein. Platelets store a large quantity of TGF-beta 1, which is released at hemorrhage. We recently reported that human recombinant TGF-beta 1 induced communicating hydrocephalus in mice. The aim of this study was to determine whether TGF-beta 1 is related to the development of communicating hydrocephalus after subarachnoid hemorrhage (SAH). METHODS: TGF-beta 1 in the cerebrospinal fluid of 24 patients with SAH was measured with enzyme-linked immunosorbent assay. The levels were compared between hydrocephalic and nonhydrocephalic groups. Western blot analysis was performed to determine active TGF-beta 1 in the cerebrospinal fluid. RESULTS: TGF-beta 1 rapidly decreased from the onset of SAH. The level of TGF-beta 1 of 13 patients showing ventricular dilatation with periventricular low density on computed tomographic scan was 1.07 +/- 0.37 ng/mL on days 12 through 14, which was significantly higher than 0.52 +/- 0.21 ng/mL in patients without ventricular dilatation (P < .02). Furthermore, the TGF-beta 1 level of patients who had undergone ventriculoperitoneal shunt (n = 11) was 1.11 +/- 0.09 ng/mL on days 12 through 14, which was also higher than the level of the nonshunt group (n = 13) (0.56 +/- 0.22 ng/mL; P < .01). A 25-kD band was demonstrated by Western blot analysis in the cerebrospinal fluid of a patient with SAH. CONCLUSIONS: Our results strongly suggest that TGF-beta 1 plays an important role in generating communicating hydrocephalus after SAH.

Intraventricular streptokinase increases cerebrospinal fluid D dimer in preterm infants with posthaemorrhagic ventricular dilatation.

Failure to lyse multiple small blood clots in the cerebrospinal fluid (CSF) reabsorption pathways may be one of the mechanisms leading to posthaemorrhagic ventricular dilatation (PHVD). It has been suggested that intraventricular administration of streptokinase may resolve PHVD but it is not known whether such treatment produces an increase in fibrin degradation products in the CSF. Ventricular CSF was collected from six infants with PHVD before and during intraventricular treatment with streptokinase 1000 units/h. In all six infants, CSF D dimer increased during streptokinase treatment. Median D dimer before treatment was 1642 micrograms/l and during treatment 5440 micrograms/l (p < 0.05). Undetectable D dimer levels in plasma during streptokinase treatment ruled out the possibility that D dimer had merely diffused into the CSF. This augmentation of local fibrinolysis may have therapeutic potential. There was no evidence of systemic fibrinolysis.