Your search keyword '"Garnett, M"' showing total 10 results

1. Lower Breakpoint of Intracranial Amplitude-Pressure Relationship in Normal Pressure Hydrocephalus.

Author

Czosnyka ZH, Lalou AD, Nabbanja E, Garnett M, Keong NC, Schmidt EA, Kim DJ, and Czosnyka M

Subjects

Brain diagnostic imaging, Humans, Neurosurgical Procedures, Hydrocephalus, Normal Pressure surgery, Intracranial Pressure

Abstract

The relationship between intracranial pulse amplitude (AMP) and mean intracranial pressure (ICP) has been previously described. Generally, AMP increases proportionally to rises in ICP. However, at low ICP a lower breakpoint (LB) of amplitude-pressure relationship can be observed, below which pulse amplitude stays constant when ICP varies. Theoretically, below this breakpoint, the pressure-volume relationship is linear (good compensatory reserve, brain compliance stays constant); above the breakpoint, it is exponential (brain compliance decreases with rising ICP).Infusion tests performed in 169 patients diagnosed for idiopathic normal pressure hydrocephalus (iNPH) during the period 2004-2013 were available for analysis. A lower breakpoint was observed in 62 patients diagnosed for iNPH. Improvement after shunt surgery in patients in whom LB was recorded was 77% versus 90% in patients where LB was absent (p < 0.02). There was no correlation between improvement and slope of amplitude-pressure line above LB.The detection of a lower breakpoint is associated with less frequent improvement after shunting in NPH. It may be interpreted that cerebrospinal fluid dynamics of patients working on the flat part of the pressure-volume curve and having a 'luxurious' compensatory reserve, are more frequently caused by brain atrophy, which is obviously not responding to shunting.

Published

2021

2. Cerebrospinal fluid dynamics in non-acute post-traumatic ventriculomegaly.

Author

Lalou AD, Levrini V, Czosnyka M, Gergelé L, Garnett M, Kolias A, Hutchinson PJ, and Czosnyka Z

Subjects

Adult, Aged, Brain Injuries, Traumatic complications, Brain Injuries, Traumatic physiopathology, Female, Humans, Hydrocephalus etiology, Hydrocephalus physiopathology, Hydrocephalus, Normal Pressure cerebrospinal fluid, Hydrocephalus, Normal Pressure physiopathology, Hydrodynamics, Male, Middle Aged, Retrospective Studies, Brain Injuries, Traumatic cerebrospinal fluid, Cerebrospinal Fluid physiology, Hydrocephalus cerebrospinal fluid, Intracranial Pressure physiology

Abstract

Background: Post-traumatic hydrocephalus (PTH) is potentially under-diagnosed and under-treated, generating the need for a more efficient diagnostic tool. We aim to report CSF dynamics of patients with post-traumatic ventriculomegaly., Materials and Methods: We retrospectively analysed post-traumatic brain injury (TBI) patients with ventriculomegaly who had undergone a CSF infusion test. We calculated the resistance to CSF outflow (Rout), AMP (pulse amplitude of intracranial pressure, ICP), dAMP (AMPplateau-AMPbaseline) and compensatory reserve index correlation coefficient between ICP and AMP (RAP). To avoid confounding factors, included patients had to be non-decompressed or with cranioplasty > 1 month previously and Rout > 6 mmHg/min/ml. Compliance was assessed using the elasticity coefficient. We also compared infusion-tested TBI patients selected for shunting versus those not selected for shunting (consultant decision based on clinical and radiological assessment and the infusion results). Finally, we used data from a group of shunted idiopathic Normal Pressure Hydrocephalus (iNPH) patients for comparison., Results: Group A consisted of 36 patients with post-traumatic ventriculomegaly and Group B of 45 iNPH shunt responders. AMP and dAMP were significantly lower in Group A than B (0.55 ± 0.39 vs 1.02 ± 0.72; p < 0.01 and 1.58 ± 1.21 vs 2.76 ± 1.5; p < 0.01. RAP baseline was not significantly different between the two. Elasticity was higher than the normal limit in all groups (average 0.18 1/ml). Significantly higher Rout was present in those with probable PTH selected for shunting compared with unshunted. Mild/moderate hydrocephalus, ex-vacuo ventriculomegaly/encephalomalacia were inconsistently reported in PTH patients., Conclusions: Rout and AMP were significantly lower in PTH compared to iNPH and did not always reflect the degree of hydrocephalus or atrophy reported on CT/MRI. Compliance appears reduced in PTH.

Published

2020

3. Thresholds for identifying pathological intracranial pressure in paediatric traumatic brain injury.

Author

Kayhanian S, Young AMH, Ewen RL, Piper RJ, Guilfoyle MR, Donnelly J, Fernandes HM, Garnett M, Smielewski P, Czosnyka M, Agrawal S, and Hutchinson PJ

Subjects

Adolescent, Brain Injuries, Traumatic diagnostic imaging, Child, Child, Preschool, Female, Humans, Male, Retrospective Studies, Tomography, X-Ray Computed, Brain Injuries, Traumatic diagnosis, Brain Injuries, Traumatic physiopathology, Intracranial Pressure

Abstract

Intracranial pressure (ICP) monitoring forms an integral part of the management of severe traumatic brain injury (TBI) in children. The prediction of elevated ICP from imaging is important when deciding on whether to implement invasive ICP monitoring for a patient. However, the radiological markers of pathologically elevated ICP have not been specifically validated in paediatric studies. Here in, we describe an objective, non-invasive, quantitative method of stratifying which patients are likely to require invasive monitoring. A retrospective review of patients admitted to Cambridge University Hospital's Paediatric Intensive Care Unit between January 2009 and December 2016 with a TBI requiring invasive neurosurgical monitoring was performed. Radiological biomarkers of TBI (basal cistern volume, ventricular volume, volume of extra-axial haematomas) from CT scans were measured and correlated with epochs of continuous high frequency variables of pressure monitoring around the time of imaging. 38 patients were identified. Basal cistern volume was found to correlate significantly with opening ICP (r = -0.53, p < 0.001). The optimal threshold of basal cistern volume for predicting high ICP ([Formula: see text]20 mmHg) was a relative volume of 0.0055 (sensitivity 79%, specificity 80%). Ventricular volume and extra-axial haematoma volume did not correlate significantly with opening ICP. Our results show that the features of pathologically elevated ICP in children may differ considerably from those validated in adults. The development of quantitative parameters can help to predict which patients would most benefit from invasive neurosurgical monitoring and we present a novel radiological threshold for this.

Published

2019

4. Validation of Davson's equation in patients suffering from idiopathic normal pressure hydrocephalus.

Author

Lalou AD, Levrini V, Garnett M, Nabbanja E, Kim DJ, Gergele L, Bjornson A, Czosnyka Z, and Czosnyka M

Subjects

Aged, Aged, 80 and over, Cranial Sinuses, Female, Humans, Hydrocephalus, Normal Pressure physiopathology, Male, Retrospective Studies, Software, Hydrocephalus, Normal Pressure diagnosis, Intracranial Pressure physiology

Abstract

Introduction: The so-called Davson's equation relates baseline intracranial pressure (ICP) to resistance to cerebrospinal fluid outflow (Rout), formation of cerebrospinal fluid (I f ) and sagittal sinus pressure (P SS ) There is a controversy over whether this fundamental equation is applicable in patients with normal pressure hydrocephalus (NPH). We investigated the relationship between Rout and ICP and also other compensatory, clinical and demographic parameters in NPH patients., Method: We carried out a retrospective study of 229 patients with primary NPH who had undergone constant-rate infusion studies in our hospital. Data was recorded and processed using ICM+ software. Relationships between variables were sought by calculating Pearson product correlation coefficients and p values., Results: We found a significant, albeit weak, relationship between ICP and Rout (R = 0.17, p = 0.0049), Rout and peak-to-peak amplitude of ICP (AMP) (R = 0.27, p = 3.577e-05) and Rout and age (R = 0.16, p = 0.01306)., Conclusions: The relationship found between ICP and Rout provides indirect evidence to support disturbed Cerebrospinal fluid circulation as a key factor in disturbed CSF dynamics in NPH. Weak correlation may indicate that other factors-variable P SS and formation of CSF outflow-contribute heavily to linear model expressed by Davson's equation.

Published

2018

5. Are Slow Waves of Intracranial Pressure Suppressed by General Anaesthesia?

Author

Lalou DA, Czosnyka M, Donnelly J, Lavinio A, Pickard JD, Garnett M, and Czosnyka Z

Subjects

Adolescent, Adult, Aged, Aged, 80 and over, Anesthetics, Intravenous pharmacology, Female, Humans, Intracranial Pressure drug effects, Male, Middle Aged, Monitoring, Physiologic, Young Adult, Anesthesia, General, Brain Injuries, Traumatic physiopathology, Hydrocephalus physiopathology, Hydrocephalus, Normal Pressure physiopathology, Intracranial Pressure physiology

Abstract

Objectives: Slow waves of intracranial pressure (ICP) are spontaneous oscillations with a frequency of 0.3-4 cycles/min. They are often associated with pathological conditions, following vasomotor activity in the cranial enclosure. This study quantifies the effects of general anaesthesia (GA) on the magnitude of B-waves compared with natural sleep and the conscious state., Materials and Methods: Four groups of 30 patients each were formed to assess the magnitude of slow waves. Group A and group B consisted of normal pressure hydrocephalus (NPH) patients, each undergoing cerebrospinal fluid (CSF) infusion studies, conscious and under GA respectively. Group C comprised conscious, naturally asleep hydrocephalic patients undergoing overnight ICP monitoring; group D, which included deeply sedated head injury patients monitored in the intensive care unit (ICU), was compared with group C., Results: The average amplitude for group A patients was higher (0.23 ± 0.10 mmHg) than that of group B (0.15 ± 0.10 mmHg; p = 0.01). Overnight magnitude of slow waves was higher in group C (0.20 ± 0.13 mmHg) than in group D (0.11 ± 0.09 mmHg; p = 0.002)., Conclusion: Slow waves of ICP are suppressed by GA and deep sedation. When using slow waves in clinical decision-making, it is important to consider the patients' level of consciousness to avoid incorrect therapeutic and management decisions.

Published

2018

6. Is There a Link Between ICP-Derived Infusion Test Parameters and Outcome After Shunting in Normal Pressure Hydrocephalus?

Author

Nabbanja E, Czosnyka M, Keong NC, Garnett M, Pickard JD, Lalou DA, and Czosnyka Z

Subjects

Adult, Aged, Aged, 80 and over, Female, Humans, Hydrocephalus, Normal Pressure diagnosis, Hydrocephalus, Normal Pressure surgery, Infusions, Spinal, Male, Middle Aged, Prognosis, Retrospective Studies, Treatment Outcome, Cerebrospinal Fluid Shunts, Hydrocephalus, Normal Pressure physiopathology, Intracranial Pressure physiology

Abstract

Objective: The term "hydrocephalus" encompasses a range of disorders characterised by clinical symptoms, abnormal brain imaging and derangement of cerebrospinal fluid (CSF) dynamics. The ability to elucidate which patients would benefit from CSF diversion (a shunt or third ventriculostomy) is often unclear. Similar difficulties are encountered in shunted patients to predict the scope for improvement by shunt re-adjustment or revision., Materials and Methods: We compared retrospective pre-shunting infusion test results performed in 310 adult patients diagnosed with normal pressure hydrocephalus (NPH) and their improvement after shunting., Results: Resistance to CSF outflow correlated significantly with improvement (p < 0.05). Other markers known from the literature, such as amplitude in CSF pulse pressure, the slope of the amplitude-pressure regression line, or elasticity did not show any correlation with outcome., Conclusion: Outcome following shunting in adult NPH is associated with resistance to CSF outflow; however, the latter cannot be taken as an absolute predictor of shunt response.

Published

2018

7. Intracranial pressure, its components and cerebrospinal fluid pressure-volume compensation.

Author

Kasprowicz M, Lalou DA, Czosnyka M, Garnett M, and Czosnyka Z

Subjects

Humans, Hydrocephalus cerebrospinal fluid, Intracranial Pressure physiology

Abstract

Clinical measurement of intracranial pressure (ICP) is often performed to aid diagnosis of hydrocephalus. This review discusses analysis of ICP and its components' for the investigation of cerebrospinal fluid (CSF) dynamics. The role of pulse, slow and respiratory waveforms of ICP in diagnosis, prognostication and management of hydrocephalus is presented. Two methods related to ICP measurement are listed: an overnight monitoring of ICP and a constant-rate infusion study. Due to the dynamic nature of ICP, a 'snapshot' manometric measurement of ICP is of limited use as it might lead to unreliable results. Therefore, monitoring of ICP over longer time combined with analysis of its waveforms provides more detailed information on the state of pressure-volume compensation. The infusion study implements ICP signal processing and CSF circulation model analysis in order to assess the cerebrospinal dynamics variables, such as CSF outflow resistance, compliance of CSF space, pressure amplitude, reference pressure, and CSF formation. These parameters act as an aid tool in diagnosis and prognostication of hydrocephalus and can be helpful in the assessment of a shunt malfunction., (© 2015 John Wiley & Sons A/S. Published by John Wiley & Sons Ltd.)

Published

2016

8. Influence of general anaesthesia on slow waves of intracranial pressure.

Author

Lalou DA, Czosnyka M, Donnelly J, Lavinio A, Pickard JD, Garnett M, and Czosnyka Z

Subjects

Aged, Aged, 80 and over, Case-Control Studies, Cerebrovascular Circulation physiology, Cognition Disorders etiology, Cohort Studies, Consciousness, Female, Humans, Hydrocephalus, Normal Pressure complications, Hydrocephalus, Normal Pressure diagnostic imaging, Hydrocephalus, Normal Pressure surgery, Intracranial Pressure physiology, Male, Perfusion, Periodicity, Anesthesia, General, Cerebrovascular Circulation drug effects, Hydrocephalus, Normal Pressure physiopathology, Intracranial Pressure drug effects

Abstract

Objective: Slow vasogenic intracranial pressure (ICP) waves are spontaneous ICP oscillations with a low frequency bandwidth of 0.3-4 cycles/min (B-waves). B-waves reflect dynamic oscillations in cerebral blood volume associated with autoregulatory cerebral vasodilation and vasoconstriction. This study quantifies the effects of general anaesthesia (GA) on the magnitude of B-waves compared to natural sleep and conscious state., Materials and Methods: The magnitude of B-waves was assessed in 4 groups of 30 patients each with clinical indications for ICP monitoring. Normal pressure hydrocephalus patients undergoing Cerebrospinal Fluid (CSF) infusion studies in the conscious state (GROUP A) and under GA (GROUP B), and hydrocephalus patients undergoing overnight ICP monitoring during physiological sleep (GROUP C) were compared to deeply sedated traumatic brain injury (TBI) patients with well-controlled ICP during the first night of Intensive Care Unit (ICU) stay (GROUP D)., Results: A total of 120 patients were included. During CSF infusion studies, the magnitude of slow waves was higher in conscious patients (, Group a: 0.23+/-0.10 mm Hg) when compared to anaesthetised patients (, Group B: 0.15+/-0.10 mm Hg; p = 0.011). Overnight magnitude of slow waves was higher in patients during natural sleep (GROUP C: 0.20+/-0.13 mm Hg) when compared to TBI patients under deep sedation (GROUP D: 0.11+/- 0.09 mm Hg; p = 0.002)., Conclusion: GA and deep sedation are associated with a reduced magnitude of B-waves. ICP monitoring carried out under GA is affected by iatrogenic suppression of slow vasogenic waves of ICP. Accounting for the effects of anaesthesia on vasogenic waves may prevent the misidentification of potential shunt-responders as non-responders.

Published

2016

9. Assessment of non-invasive ICP during CSF infusion test: an approach with transcranial Doppler.

Author

Cardim D, Czosnyka M, Donnelly J, Robba C, Cabella BC, Liu X, Cabeleira MT, Smielewsky P, Haubrich C, Garnett MR, Pickard JD, and Czosnyka Z

Subjects

Adult, Blood Flow Velocity, Cerebrovascular Circulation, Female, Humans, Male, Middle Aged, Prospective Studies, Hydrocephalus diagnostic imaging, Intracranial Pressure, Ultrasonography, Doppler, Transcranial

Abstract

Background: This study aimed to compare four non-invasive intracranial pressure (nICP) methods in a prospective cohort of hydrocephalus patients whose cerebrospinal fluid dynamics was investigated using infusion tests involving controllable test-rise of ICP., Method: Cerebral blood flow velocity (FV), ICP and non-invasive arterial blood pressure (ABP) were recorded in 53 patients diagnosed for hydrocephalus. Non-invasive ICP methods were based on: (1) interaction between FV and ABP using black-box model (nICP&#95;BB); (2) diastolic FV (nICP&#95;FVd); (3) critical closing pressure (nICP&#95;CrCP); (4) transcranial Doppler-derived pulsatility index (nICP&#95;PI). Correlation between rise in ICP (∆ICP) and ∆nICP and averaged correlations for changes in time between ICP and nICP during infusion test were investigated., Results: From baseline to plateau, all nICP estimators increased significantly. Correlations between ∆ICP and ∆nICP were better represented by nICP&#95;PI and nICP&#95;BB: 0.45 and 0.30 (p < 0.05). nICP&#95;FVd and nICP&#95;CrCP presented non-significant correlations: -0.17 (p = 0.21), 0.21 (p = 0.13). For changes in ICP during individual infusion test nICP&#95;PI, nICP&#95;BB and nICP&#95;FVd presented similar correlations with ICP: 0.39 ± 0.40, 0.39 ± 0.43 and 0.35 ± 0.41 respectively. However, nICP&#95;CrCP presented a weaker correlation (R = 0.29 ± 0.24)., Conclusions: Out of the four methods, nICP&#95;PI was the one with best performance for predicting changes in ∆ICP during infusion test, followed by nICP&#95;BB. Unreliable correlations were shown by nICP&#95;FVd and nICP&#95;CrCP. Changes of ICP observed during the test were expressed by nICP values with only moderate correlations.

Published

2016

10. Shunt Testing In Vivo: Observational Study of Problems with Ventricular Catheter.

Author

Czosnyka ZH, Sinha R, Morgan JA, Wawrzynski JR, Price SJ, Garnett M, Pickard JD, and Czosnyka M

Subjects

Equipment Failure, Humans, Infusions, Parenteral methods, Reoperation, Slit Ventricle Syndrome surgery, Spinal Puncture methods, Cerebrospinal Fluid Shunts instrumentation, Hydrocephalus surgery, Intracranial Pressure, Slit Ventricle Syndrome diagnosis

Abstract

Most shunt obstructions happen at the inlet of the ventricular catheter. Three hundred six infusion studies from 2007 to 2011 were classified as having a typical pattern of either proximal occlusion or patency. We describe different patterns of shunt ventricular obstruction.Solid block: Cerebrospinal fluid (CSF) aspiration was impossible. Baseline pressure was without pulse waveform (respiratory waveform may be visible). A quick increase of pressure to a level compatible with the shunt's setting was recorded in response to infusion. Distal occlusion of the shunt via transcutaneous compression resulted in a rapid increase in pressure to levels above 50 mmHg. This pattern was attributed to a solid ventricular block.Slit ventricles: At baseline, a pattern similar to that of the solid block was observed. After compression, the pressure increases, the pulse waveform appears, and the intracranial pressure is often stabilized at 25-40 mmHg. It is probable that previously slit ventricles were opened during the test.Partial block: In a partial block of the ventricular catheter by an in-growing choroid plexus, the pulse waveform at baseline was observed and CSF aspiration was possible. During infusion, the pressure increased, but the pulse amplitude disappeared. During the increase in the pressure in the shunt prechamber, the connection with the ventricles is disturbed by repositioning of the plexus.Infusion study via the shunt prechamber is able to visualize ventricular obstruction of the hydrocephalus shunt.

Published

2016