Abstract: Apparatus for the diagnostics and treatment of conditions presenting as intracranial circulation maladies in reliance upon segmental intracranial compartment pressure, which is established from the interdynamics between intra-cranial and extra-cranial circulation, and which relies upon compression of the extra-cranial vascular network in order to: measure cranial inflow and outflow pressure in the intra-extra cranial collateral (e.g., in the network supplied by the supraorbital artery), to estimate intracranial compartment segmental perfusion pressure; temporarily augment intracranial inflow pressure during a period of the compromise (e.g., common carotid cross-clamp during carotid endarterectomy or extracranial stenosis with low-flow state) and redirect extracranial blood-flow intracranially to augment cerebral circulation and/or introduce therapeutic agents or cold blood to the intracranial compartment.

Abstract: A patient in whom blood diversion due to cerebral venous steal is present, and abolishment of the cerebral venous steal is indicated, is treated by increasing the cerebral venous pressure in the patient. This increase in cerebral venous pressure restores the collapsed cerebral vasculature, thereby increasing cerebral blood flow. The increase in cerebral venous pressure may be achieved using an occluding catheter in the superior vena cava or the internal jugular veins, using external compression of the cervical veins, or any other suitable mechanism. The occlusion may be controlled precisely during treatment, possibly as a function of cerebral blood flow, and after treatment the patient may experience a persistent effect because the cerebral vasculature is no longer collapsed.

Abstract: A system for detecting and measuring increased global or local intracranial pressure includes various devices for performing controlled occlusion of jugular cranial blood outflow and generating occlusion data related to said controlled occlusion, a cranial blood outflow pressure measurement device and a processor for processing jugular cranial blood outflow occlusion data and cranial blood outflow data to identify and/or measure a functional relationship between the jugular controlled occlusion and the jugular cranial blood outflow pressure. A device communicates the functional relationship a display device and/or a patient monitoring system. The processor also detects a state of equilibrium between the jugular cranial blood outflow pressure and the jugular occlusion pressure at occlusion.

Abstract: A patient in whom blood diversion due to cerebral venous steal is present, and abolishment of the cerebral venous steal is indicated, is treated by increasing the cerebral venous pressure in the patient. This increase in cerebral venous pressure restores the collapsed cerebral vasculature, thereby increasing cerebral blood flow. The increase in cerebral venous pressure may be achieved using an occluding catheter in the superior vena cava or the internal jugular veins, using external compression of the cervical veins, or any other suitable mechanism. The occlusion may be controlled precisely during treatment, possibly as a function of cerebral blood flow, and after treatment the patient may experience a persistent effect because the cerebral vasculature is no longer collapsed.

Abstract: Method to obtain continuous recording of the central arterial blood pressure waveform noninvasively utilizes dual (distal occlusion and proximal) brachial artery occlusion cuffs and dual external osculation. The distal arterial occlusion cuff eliminates venous stasis artifact and flow related gradient from aorta to the brachial artery. The proximal cuff measures, and delivers, dual external oscillation. The dual external oscillation allows measurement of the arterial compliance at a multitude of transmural pressure values during each cardiac cycle. Transmural pressure/arterial compliance and arterial pressure curves are subsequently reconstructed using dual external oscillation. The curves consist of two parts, rapid and slow parts, both at the frequency higher than the arterial pulse.

Abstract: A system for detecting and measuring increased global or local intracranial pressure includes various devices for performing controlled occlusion of jugular cranial blood outflow and generating occlusion data related to said controlled occlusion, a cranial blood outflow pressure measurement device and a processor for processing jugular cranial blood outflow occlusion data and cranial blood outflow data to identify and/or measure a functional relationship between the jugular controlled occlusion and the jugular cranial blood outflow pressure. A device communicates the functional relationship a display device and/or a patient monitoring system. The processor also detects a state of equilibrium between the jugular cranial blood outflow pressure and the jugular occlusion pressure at occlusion.

Abstract: A method to measure effective cerebral outflow pressure or intracranial pressure is disclosed. The craniospinal venous system has multiple anastomoses between the jugular veins and vertebral venous plexus. Jugular veins collapse with cervical compression or head elevation, when extrinsic pressure exceeds venous pressure. The vertebral venous plexus is exposed to intracranial pressure and collapses when intracranial pressure exceeds venous pressure. Vertebral venous plexus is not compressed with head elevation or cervical compression, because enclosure in the spinal canal protects veins from the direct effects of atmospheric pressure and cervical compression. Using cervical compression and/or head elevation blood outflow is redistributed between jugular veins and vertebral venous plexus, while the degree of cervical compression or head elevation indicates effective cerebral outflow pressure or ICP.

Abstract: A patient in whom blood diversion due to cerebral venous steal is present, and abolishment of the cerebral venous steal is indicated, is treated by increasing the cerebral venous pressure in the patient. This increase in cerebral venous pressure restores the collapsed cerebral vasculature, thereby increasing cerebral blood flow. The increase in cerebral venous pressure may be achieved using an occluding catheter in the superior vena cava or the internal jugular veins, using external compression of the cervical veins, or any other suitable mechanism. The occlusion may be controlled precisely during treatment, possibly as a function of cerebral blood flow, and after treatment the patient may experience a persistent effect because the cerebral vasculature is no longer collapsed.

Abstract: Current noninvasive blood pressure measurement methods are not able to measure pressure during nonpulsatile blood flow. We propose method to measure intravascular or other compartment pressure which applies extrinsic pressure oscillation. Pressure-volume response of the compressed structure is obtained and compartment pressure is estimated as the extrinsic pressure at which compressed structure has the highest compliance. Delivering extrinsic oscillations at a higher frequency than the pulse rate, pressure reading can be obtained much faster. Because it is not dependant on intrinsic vascular oscillations, pressure can be measured during arrhythmias, during cardiac bypass, during resuscitation, in the venous compartment or in the other nonpulsatile compressible body compartments.

Abstract: Method and apparatus for detecting and treating cerebral blood vessel collapse (54) during intracranial hypertension or vasospasm by affecting cerebral venous outflow pressure (61). Venous collapse is diagnosed by lowering jugular venous bulb pressure (61) and detecting significant, progressively increasing gradient between it and ICP (60). Rising jugular venous pressure initially the collapse is terminated and then ICP starts to increase. Increasing jugular venous pressure opens collapsed vascular segments by increasing intravascular pressure. There is no increase in ICP if jugular venous pressure is maintained below value that affects ICP. During life-threatening vascular collapse caused by a plateau wave or vasospasm venous outflow pressure is temporarily increased to a level necessary to terminate collapse regardless of ICP. This is accomplished by venous occlusion catheter placed into dominant jugular vein.