Benign Intracranial Hypertension with Particular Reference to Its Occurrence in Fat Young Women

Benign intracranial hypertension (pseudotumor cerebri), a syndrome common to a number of disorders, is characterized by headaches and blurred vision. The patient is alert and has papilledema without localizing signs. Air studies show normal ventricles under increased pressure. The authors describe 61 consecutive cases of this pseudotumour, 48 of which were in fat young women, and propose that this group represents a clinical entity that has hitherto received little attention.In these 61 patients, 40 complete-exchange pneumoencephalograms showed normal ventricles, normal fluid volume and prominent cortical sulci. In 32, subtemporal decompression resulted in prompt and lasting relief. Three patients had late convulsive seizures after surgery. Seven patients had nasal quadrantanopsias, the implications of which are discussed. The authors believe that the high intracranial pressure in this condition is due to cerebral hyperemia, not brain edema. Further investigation will perhaps demonstrate a relationship between obesity, vascular dilatation and increased intracranial pressure.     

Relation between resorption resistance of cerebrospinal fluid and the degree of intracranial pressure]

Changes in the CSF resorption resistance in relation to the value of the intracranial pressure have been assessed in 44 cats. Changes in the intracranial pressure have been produced with fluid infusions. Between 1 to 5 infusion tests with the rate 0.012-1.8 ml/min have been performed in each animal. A relationship between CSF resorption resistance and intracranial pressure has been found. With an increase in the intracranial pressure CSF resorption resistance increased to maximum value of 34 kPa/ml per minute (255.6 mm Hg/ml per minute) at pressure 2.96 +/- 0.69 kPa (22.2 +/- 5.2 mm Hg). At the intracranial pressure about 6.7 kPa (50 mm Hg) CSF resorption resistance rapidly decreased to the value of 13.9 kPa/ml per minute (104 mm Hg/ml per minute). Later, changes have been rather slight. It is possible, that the breaking point at 6.7 kPa corresponds to the mobilisation of all ways of CSF evacuation.     

The Influence of Body Position on Cerebrospinal Fluid Pressure Gradient and Movement in Cats with Normal and Impaired Craniospinal Communication

Intracranial hypertension is a severe therapeutic problem, as there is insufficient knowledge about the physiology of cerebrospinal fluid (CSF) pressure. In this paper a new CSF pressure regulation hypothesis is proposed. According to this hypothesis, the CSF pressure depends on the laws of fluid mechanics and on the anatomical characteristics inside the cranial and spinal space, and not, as is today generally believed, on CSF secretion, circulation and absorption. The volume and pressure changes in the newly developed CSF model, which by its anatomical dimensions and basic biophysical features imitates the craniospinal system in cats, are compared to those obtained on cats with and without the blockade of craniospinal communication in different body positions. During verticalization, a long-lasting occurrence of negative CSF pressure inside the cranium in animals with normal cranio-spinal communication was observed. CSF pressure gradients change depending on the body position, but those gradients do not enable unidirectional CSF circulation from the hypothetical site of secretion to the site of absorption in any of them. Thus, our results indicate the existence of new physiological/pathophysiological correlations between intracranial fluids, which opens up the possibility of new therapeutic approaches to intracranial hypertension.     

Increased CSF levels of somatostatin in patients with brain tumours and intracranial hypertension

The cerebrospinal fluid (CSF) levels of somatostatin in patients with brain tumours, communicating hydrocephalus, lumbar-disc disease (treated as a control) were measured by specific radioimmunoassay. The somatostatin concentration in the patients with brain tumours and intracranial hypertension was significantly higher compared to those with brain tumours and normal CSF pressure. CSF somatostatin content in patients with communicating hydrocephalus, was similar to patients with brain tumours and normal CSF pressure, and did not show a significant difference from the control group. The authors discuss possible reasons for such results obtained in patients with brain tumours and intracranial hypertension.     

Pressure balance and imbalance in the optic nerve chamber: The Beijing Intracranial and Intraocular Pressure (iCOP) Study

To determine the interdependence of intracranial pressure (ICP) and intraocular pressure (IOP) and how it affects optic nerve pressures, eight normal dogs were examined using pressure-sensing probes implanted into the left ventricle, lumbar cistern, optic nerve subarachnoid space in the left eye, and anterior chamber in the left eye. This allowed ICP, lumbar cistern pressure (LCP), optic nerve subarachnoid space pressure (ONSP) and IOP to be simultaneously recorded. After establishing baseline pressure levels, pressure changes that resulted from lowering ICP (via shunting cerebrospinal fluid (CSF) from the ventricle) were recorded. At baseline, all examined pressures were different (ICP<LCP<ONSP), but correlated (P>0.001). As ICP was lowered during CSF shunting, IOP also dropped in a parallel time course so that the trans-lamina cribrosa gradient (TLPG) remained stable (ICP-IOP dependent zone). However, once ICP fell below a critical breakpoint, ICP and IOP became uncoupled and TLPG changed as ICP declined (ICP-IOP independent zone). The optic nerve pressure gradient (ONPG) and trans-optic nerve pressure gradient (TOPG) increased linearly as ICP decreased through both the ICP-IOP dependent and independent zones. We conclude that ICP and IOP are coupled in a specific pressure range, but when ICP drops below a critical point, IOP and ICP become uncoupled and TLPG increases. When ICP drops, a rise in the ONPG and TOPG creates more pressure and reduces CSF flow around the optic nerve. This change may play a role in the development and progression of various ophthalmic and neurological diseases, including glaucoma.     

Pseudotumor cerebri during pregnancy

Pseudotumor cerebri (PTC) is characterized by increased intracranial pressure and papilledema in the absence of other neurologic localizing signs. Headaches and other visual disturbances may also exist. PTC or benign intracranial hypertension has been estimated to have an incidence of approximately 1 in 1000 pregnancies [Katz VL, Peterson R, Cefalo RC. Am J Perinatol 1989;6:442–445]. The following case report presents a patient with PTC during pregnancy. The clinical features of the disease, management strategies and differential diagnoses will be discussed.     

Human head dynamic response to side impact by finite element modeling

The dynamic response of the human head to side impact was studied by 2-dimensional finite element modeling. Three models were formulated in this study. Model I is an axisymmetric model. It simulated closed shell impact of the human head, and consisted of a single-layered spherical shell filled wiht an inviscid fluid. The other two models (Model II and III) are plane strain models of a coronal section of the human head. Model II approximated a 50th percentile male head by an outer layer to simulate cranial bone and an inviscid interior core to simulate the intracranial contents. The configuration of Model III is the same as Model II but more detailed anatomical features of the head interior were added, such as, cerebral spinal fluid (CSF); falx cerebri, dura, and tentorium. Linear elastic material properties were assigned to all three models. All three models were loaded by a triangular pulse with a peak pressure of 40 kPa, effectively producing a peak force of 1954 N (440 lb). The purpose of this study was to determine the effects of the membranes and that of the mechanical properties of the skull, brain, and membrane on the dynamic response of the brain during side impact, and to compare the pressure distributions from the plane strain model with the axisymmetric model. A parametric study was conducted on Model II to characterize fully its response to impact under various conditions.(ABSTRACT TRUNCATED AT 250 WORDS)     

Graves' disease presenting as pseudotumor cerebri: a case report

Introduction

Pseudotumor cerebri is an entity characterized by elevated intracranial pressure with normal cerebrospinal fluid and no structural abnormalities detected on brain MRI scans. Common secondary causes include endocrine pathologies. Hyperthyroidism is very rarely associated and only three case reports have been published so far.

Case presentation

We report the case of a 31-year-old Luso-African woman with clinical symptoms and laboratory confirmation of Graves' disease that presented as pseudotumor cerebri.

Conclusion

This is a rare form of presentation of Graves' disease and a rare cause of pseudotumor cerebri. It should be remembered that hyperthyroidism is a potential cause of pseudotumor cerebri.

     

Mechanism of the decrease in intracranial pressure as affected by furosemide

The correlation was established between the increase in diuresis and natriuresis and fall of CSF pressure after intravenous injection of 10 mg/kg furosemide into dogs. Osmolarity and ion concentration in the serum and CSF did not change in these experiments. In nephrectomized dogs, furosemide did not changes CSF pressure. Furosemide dehydrated brain with traumatic edema, reduced brain Fe content probably due to diminishing brain blood content. The mechanism of intracranial pressure fall after furosemide injection can be explained by acute excretion of a large volume of fluid by the kidneys, leading to a decrease in the blood content of the skull cavity.     

Intracranial pressure accommodation is impaired by blocking pathways leading to extracranial lymphatics

Tracer studies indicate that cerebrospinal fluid (CSF) transport can occur through the cribriform plate into the nasal submucosa, where it is absorbed by cervical lymphatics. We tested the hypothesis that sealing the cribriform plate extracranially would impair the ability of the CSF pressure-regulating systems to compensate for volume infusions. Sheep were challenged with constant flow or constant pressure infusions of artificial CSF into the CSF compartment before and after the nasal mucosal side of the cribriform plate was sealed. With both infusion protocols, the intracranial pressure (ICP) vs. flow rate relationships were shifted significantly to the left when the cribriform plate was blocked. This indicated that obstruction of the cribriform plate reduced CSF clearance. Sham surgical procedures had no significant effects. Estimates of the proportional flow through cribriform and noncribriform routes suggested that cranial CSF absorption occurred primarily through the cribriform plate at low ICPs. Additional drainage sites (arachnoid villi or other lymphatic pathways) appeared to be recruited only when intracranial pressures were elevated. These data challenge the conventional view that CSF is absorbed principally via arachnoid villi and provide further support for the existence of several anatomically distinct cranial CSF transport pathways.     

Brain ribosomes in intracranial hypertension

Abstract— Increased intracranial pressure was produced by perfusion of cerebrospinal fluid (CSF) at various pressures into the lateral ventricles of adult Sprague-Dawley rats with bilateral chronic intraventricular cannulas. When CSF perfusion was carried out at pressures of 150, 300 or 600 mm of water, brain polysomal profiles were similar to controls. Rats perfused under a pressure of 1500 mm water for 30 min were comatose, had slow electroencephalograms and showed a fall in brain polysomes from 66 to 24 per cent of the total ribosomes (P < 0.01) while ribosomal monomers and dimers increased. These monomers and dimers were completely and reversibly dissociated into subunits in 500 niM KC1 buffers, unless prefixed in formaldehyde. [³H]leucine incorporation into brain ribosomes in vivo was decreased by severe intracranial hypertension. In cell-free systems in vitro, pathological ribosomes were less active in protein synthesis than controls (P < 0.01) but were at least as readily stimulated by poly U. After intracranial pressure was returned to normal, there was a progressive reassociation of ribosomes into polysomes, even in the presence of Actinomycin D. These findings suggest that during severe intracranial hypertension cerebral protein synthesis is inhibited, perhaps through reversible inactivation of the translation of messenger RNA.     

Resistance to outflow of cerebrospinal fluid after central infusions of angiotensin.

Infusions of artificial cerebrospinal fluid (CSF) into the cerebroventricles of conscious rats can raise CSF pressure (CSFp). This response can be modified by some neuropeptides. One of these, angiotensin, facilitates the rise in CSFp. We measured CSFp in conscious rats with a computerized system and evaluated resistance to CSF outflow during infusion of artificial CSF, with or without angiotensin, from the decay kinetics of superimposed bolus injections. Angiotensin (10 ng/min) raised CSFp (P less than 0.05) compared with solvent, but the resistance to CSF outflow of the two groups was similar (P greater than 0.05). Because CSFp was increased by angiotensin without an increase in the outflow resistance, a change in some volume compartment is likely. Angiotensin may raise CSFp by increasing CSF synthesis; this possibility is supported, since the choroid plexuses contain an intrinsic isorenin-angiotensin system. Alternatively, angiotensin may dilate pial arteries, leading to an increased intracranial blood volume.     

A mathematical model of blood,cerebrospinal fluid and brain dynamics

Using first principles of fluid and solid mechanics a comprehensive model of human intracranial dynamics is proposed. Blood, cerebrospinal fluid (CSF) and brain parenchyma as well as the spinal canal are included. The compartmental model predicts intracranial pressure gradients, blood and CSF flows and displacements in normal and pathological conditions like communicating hydrocephalus. The system of differential equations of first principles conservation balances is discretized and solved numerically. Fluid–solid interactions of the brain parenchyma with cerebral blood and CSF are calculated. The model provides the transitions from normal dynamics to the diseased state during the onset of communicating hydrocephalus. Predicted results were compared with physiological data from Cine phase-contrast magnetic resonance imaging to verify the dynamic model. Bolus injections into the CSF are simulated in the model and found to agree with clinical measurements.

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RHEOLOGICAL OBSERVATION ONCEREBRO-SPINAL FLUID

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原发性血小板减少性紫癜合并侵袭性真菌感染2例报告附文献复习

目的 报道2例难治性原发性血小板减少性紫癜（ITP）患者用大剂量激素和（或）免疫抑制剂后发生侵袭性真菌感染（IFI）,其治疗经过及相关文献复习。方法 2例难治性ITP患者用大剂量激素和（或）免疫抑制剂后发生IFI,用大扶康、两性霉素B,降颅压,辅助呼吸等治疗。结果 例1发生隐球菌脑膜脑炎、例2出现肺曲酶菌感染,均经抗真菌治疗无效死亡。结论 长期应用激素及免疫抑制剂是难治性ITP患者发生IFI的危险因素,治疗困难,确诊后用药应足量、足疗程。     

Blocking cerebrospinal fluid absorption through the cribriform plate increases resting intracranial pressure

Cerebrospinal fluid (CSF) drains through the cribriform plate (CP) in association with the olfactory nerves. From this location, CSF is absorbed into nasal mucosal lymphatics. Recent data suggest that this pathway plays an important role in global CSF transport in sheep. In this report, we tested the hypothesis that blocking CSF transport through this pathway would elevate resting intracranial pressure (ICP). ICP was measured continuously from the cisterna magna of sheep before and after CP obstruction in the same animal. To block CSF transport through the CP, an external ethmoidectomy was performed. The olfactory and adjacent mucosa were removed, and the bone surface was sealed with tissue glue. To restrict our analysis to the cranial CSF system, CSF transport into the spinal subarachnoid compartment was prevented with a ligature tightened around the thecal sac between C1 and C2. Sham surgical procedures had no significant effects, but in the experimental group CP obstruction elevated ICP significantly. Mean postobstruction steady-state pressures (18.0 +/- 3.8 cmH(2)O) were approximately double the preobstruction values (9.2 +/- 0.9 cmH(2)O). These data support the concept that the olfactory pathway represents a major site for CSF drainage.     

Aquaporin-4 gene disruption in mice reduces brain swelling and mortality in pneumococcal meningitis

The astroglial water channel aquaporin-4 (AQP4) facilitates water movement into and out of brain parenchyma. To investigate the role of AQP4 in meningitis-induced brain edema, Streptococcus pneumoniae was injected into cerebrospinal fluid (CSF) in wild type and AQP4 null mice. AQP4-deficient mice had remarkably lower intracranial pressure (9 +/- 1 versus 25 +/- 5 cm H2O) and brain water accumulation (2 +/- 1 versus 9 +/- 1 microl) at 30 h, and improved survival (80 versus 0% survival) at 60 h, through comparable CSF bacterial and white cell counts. Meningitis produced marked astrocyte foot process swelling in wild type but not AQP4 null mice, and slowed diffusion of an inert macromolecule in brain extracellular space. AQP4 protein was strongly up-regulated in meningitis, resulting in a approximately 5-fold higher water permeability (P(f)) across the blood-brain barrier compared with non-infected wild type mice. Mathematical modeling using measured P(f) and CSF dynamics accurately simulated the elevated lower intracranial pressure and brain water produced by meningitis and predicted a beneficial effect of prevention of AQP4 upregulation. Our findings provide a novel molecular mechanism for the pathogenesis of brain edema in acute bacterial meningitis, and suggest that inhibition of AQP4 function or up-regulation may dramatically improve clinical outcome.     

On the transmission of external pressure fluctuations to the cerebrospinal fluid

A theory has been formulated to explain the manner in which external pressure fluctuations are transmitted to the cerebrospinal fluid (CSF). The theory is based upon a three-compartment model which consists of the cerebral ventricles, the basal cisterns and spinal subarachnoid space, and the cortical subarachnoid space. The external pressure disturbance is represented by a Fourier series summed over the frequency ω. The mathematical analysis leads to a time constant τ which depends upon the compliances of the spinal region and sources of external pressure fluctuations, the rate of CSF absorption and the rate of fluid transfer between compartments. For arterial pulsations where ωτ ? 1, the theory is in accord with the experimental observations that (i) the arterial and CSF pulse waves are nearly identical in shape, and (ii) the amplitude of the CSF pulse wave increases with intracranial pressure. Moreover, it predicts that the amplitude of the wave will be larger in the spinal region than in the ventricles. The theory also accounts for the observation of one per minute pulse waves observed in hydrocephalic patients with decreased absorption rates.     

Cerebrospinal Fluid Taurine after Traumatic Brain Injury

In the experimental setting, taurine is known to be released from swollen cells to reestablish their normal volume. However, its clinical relevance has not been fully understood. This study was undertaken to reveal changes in cerebrospinal fluid (CSF) amino acids concentration in patients with severe traumatic brain injury (TBI). The study included eight patients, in whom a ventricular catheter was inserted to measure intracranial pressure and obtain CSF samples for 5 days. CSF obtained from patients with normal pressure hydrocephalus served as a control. CSF taurine concentration increased 1.8 times control (P < 0.05) after TBI and returned to control value approximately 67 h after injury. Taurine decreased further and remained lower than control thereafter. Phosphoethanolamine showed similar increase, whereas glutamine decreased transiently and arginine remained close to control value. The present data support the period of astrocytic swelling observed after TBI in other morphological studies. The mechanism and consequences of CSF taurine decrease in the subacute stage of TBI need to be elucidated.