Your search keyword '"Boutelle MG"' showing total 7 results

1. Traumatic brain injury neuroelectrochemical monitoring: behind-the-ear micro-instrument and cloud application.

Author

Tageldeen MK, Gowers SAN, Leong CL, Boutelle MG, and Drakakis EM

Subjects

Brain Chemistry, Humans, Male, Biosensing Techniques instrumentation, Brain Injuries, Traumatic, Electrocorticography instrumentation, Monitoring, Ambulatory instrumentation, Neurophysiological Monitoring instrumentation

Abstract

Background: Traumatic Brain Injury (TBI) is a leading cause of fatality and disability worldwide, partly due to the occurrence of secondary injury and late interventions. Correct diagnosis and timely monitoring ensure effective medical intervention aimed at improving clinical outcome. However, due to the limitations in size and cost of current ambulatory bioinstruments, they cannot be used to monitor patients who may still be at risk of secondary injury outside the ICU., Methods: We propose a complete system consisting of a wearable wireless bioinstrument and a cloud-based application for real-time TBI monitoring. The bioinstrument can simultaneously record up to ten channels including both ECoG biopotential and neurochemicals (e.g. potassium, glucose and lactate), and supports various electrochemical methods including potentiometry, amperometry and cyclic voltammetry. All channels support variable gain programming to automatically tune the input dynamic range and address biosensors' falling sensitivity. The instrument is flexible and can be folded to occupy a small space behind the ear. A Bluetooth Low-Energy (BLE) receiver is used to wirelessly connect the instrument to a cloud application where the recorded data is stored, processed and visualised in real-time. Bench testing has been used to validate device performance., Results: The instrument successfully monitored spreading depolarisations (SDs) - reproduced using a signal generator - with an SNR of 29.07 dB and NF of 0.26 dB. The potentiostat generates a wide voltage range from -1.65V to +1.65V with a resolution of 0.8mV and the sensitivity of the amperometric AFE was verified by recording 5 pA currents. Different potassium, glucose and lactate concentrations prepared in lab were accurately measured and their respective working curves were constructed. Finally,the instrument achieved a maximum sampling rate of 1.25 ksps/channel with a throughput of 105 kbps. All measurements were successfully received at the cloud., Conclusion: The proposed instrument uniquely positions itself by presenting an aggressive optimisation of size and cost while maintaining high measurement accuracy. The system can effectively extend neuroelectrochemical monitoring to all TBI patients including those who are mobile and those who are outside the ICU. Finally, data recorded in the cloud application could be used to help diagnosis and guide rehabilitation.

Published

2020

2. A High-Performance Application Specific Integrated Circuit for Electrical and Neurochemical Traumatic Brain Injury Monitoring.

Author

Pagkalos I, Rogers ML, Boutelle MG, and Drakakis EM

Subjects

Electricity, Humans, Brain Injuries, Traumatic diagnosis, Neurophysiological Monitoring

Abstract

This paper presents the first application specific integrated chip (ASIC) for the monitoring of patients who have suffered a Traumatic Brain Injury (TBI). By monitoring the neurophysiological (ECoG) and neurochemical (glucose, lactate and potassium) signals of the injured human brain tissue, it is possible to detect spreading depolarisations, which have been shown to be associated with poor TBI patient outcome. This paper describes the testing of a new 7.5 mm 2 ASIC fabricated in the commercially available AMS 0.35 μm CMOS technology. The ASIC has been designed to meet the demands of processing the injured brain tissue's ECoG signals, recorded by means of depth or brain surface electrodes, and neurochemical signals, recorded using microdialysis coupled to microfluidics-based electrochemical biosensors. The potentiostats use switchedcapacitor charge integration to record currents with 100 fA resolution, and allow automatic gain changing to track the falling sensitivity of a biosensor. This work supports the idea of a "behind the ear" wireless microplatform modality, which could enable the monitoring of currently non-monitored mobile TBI patients for the onset of secondary brain injury., (©2018 The Authors. Published by Wiley-VCH Verlag GmbH & Co. KGaA.)

Published

2018

3. Chemical Monitoring in Clinical Settings: Recent Developments toward Real-Time Chemical Monitoring of Patients.

Author

Booth MA, Gowers SAN, Leong CL, Rogers ML, Samper IC, Wickham AP, and Boutelle MG

Subjects

Humans, Time Factors, Neurophysiological Monitoring

Published

2018

4. Simultaneous monitoring of potassium, glucose and lactate during spreading depolarization in the injured human brain - Proof of principle of a novel real-time neurochemical analysis system, continuous online microdialysis.

Author

Rogers ML, Leong CL, Gowers SA, Samper IC, Jewell SL, Khan A, McCarthy L, Pahl C, Tolias CM, Walsh DC, Strong AJ, and Boutelle MG

Subjects

Brain Injuries metabolism, Coma metabolism, Coma physiopathology, Electrocorticography, Humans, Online Systems, Brain Injuries physiopathology, Cortical Spreading Depression physiology, Glucose metabolism, Lactic Acid metabolism, Microdialysis, Neurophysiological Monitoring methods, Potassium metabolism

Abstract

Spreading depolarizations occur spontaneously and frequently in injured human brain. They propagate slowly through injured tissue often cycling around a local area of damage. Tissue recovery after an spreading depolarization requires greatly augmented energy utilisation to normalise ionic gradients from a virtually complete loss of membrane potential. In the injured brain, this is difficult because local blood flow is often low and unreactive. In this study, we use a new variant of microdialysis, continuous on-line microdialysis, to observe the effects of spreading depolarizations on brain metabolism. The neurochemical changes are dynamic and take place on the timescale of the passage of an spreading depolarization past the microdialysis probe. Dialysate potassium levels provide an ionic correlate of cellular depolarization and show a clear transient increase. Dialysate glucose levels reflect a balance between local tissue glucose supply and utilisation. These show a clear transient decrease of variable magnitude and duration. Dialysate lactate levels indicate non-oxidative metabolism of glucose and show a transient increase. Preliminary data suggest that the transient changes recover more slowly after the passage of a sequence of multiple spreading depolarizations giving rise to a decrease in basal dialysate glucose and an increase in basal dialysate potassium and lactate levels.

Published

2017

5. Recording, analysis, and interpretation of spreading depolarizations in neurointensive care: Review and recommendations of the COSBID research group.

Author

Dreier JP, Fabricius M, Ayata C, Sakowitz OW, Shuttleworth CW, Dohmen C, Graf R, Vajkoczy P, Helbok R, Suzuki M, Schiefecker AJ, Major S, Winkler MK, Kang EJ, Milakara D, Oliveira-Ferreira AI, Reiffurth C, Revankar GS, Sugimoto K, Dengler NF, Hecht N, Foreman B, Feyen B, Kondziella D, Friberg CK, Piilgaard H, Rosenthal ES, Westover MB, Maslarova A, Santos E, Hertle D, Sánchez-Porras R, Jewell SL, Balança B, Platz J, Hinzman JM, Lückl J, Schoknecht K, Schöll M, Drenckhahn C, Feuerstein D, Eriksen N, Horst V, Bretz JS, Jahnke P, Scheel M, Bohner G, Rostrup E, Pakkenberg B, Heinemann U, Claassen J, Carlson AP, Kowoll CM, Lublinsky S, Chassidim Y, Shelef I, Friedman A, Brinker G, Reiner M, Kirov SA, Andrew RD, Farkas E, Güresir E, Vatter H, Chung LS, Brennan KC, Lieutaud T, Marinesco S, Maas AI, Sahuquillo J, Dahlem MA, Richter F, Herreras O, Boutelle MG, Okonkwo DO, Bullock MR, Witte OW, Martus P, van den Maagdenberg AM, Ferrari MD, Dijkhuizen RM, Shutter LA, Andaluz N, Schulte AP, MacVicar B, Watanabe T, Woitzik J, Lauritzen M, Strong AJ, and Hartings JA

Subjects

Brain Injuries diagnosis, Brain Injuries therapy, Cerebrovascular Circulation, Electrocorticography, Humans, Practice Guidelines as Topic, Stroke diagnosis, Stroke therapy, Brain Injuries physiopathology, Cortical Spreading Depression physiology, Critical Care methods, Gray Matter physiopathology, Neurophysiological Monitoring methods, Stroke physiopathology

Abstract

Spreading depolarizations (SD) are waves of abrupt, near-complete breakdown of neuronal transmembrane ion gradients, are the largest possible pathophysiologic disruption of viable cerebral gray matter, and are a crucial mechanism of lesion development. Spreading depolarizations are increasingly recorded during multimodal neuromonitoring in neurocritical care as a causal biomarker providing a diagnostic summary measure of metabolic failure and excitotoxic injury. Focal ischemia causes spreading depolarization within minutes. Further spreading depolarizations arise for hours to days due to energy supply-demand mismatch in viable tissue. Spreading depolarizations exacerbate neuronal injury through prolonged ionic breakdown and spreading depolarization-related hypoperfusion (spreading ischemia). Local duration of the depolarization indicates local tissue energy status and risk of injury. Regional electrocorticographic monitoring affords even remote detection of injury because spreading depolarizations propagate widely from ischemic or metabolically stressed zones; characteristic patterns, including temporal clusters of spreading depolarizations and persistent depression of spontaneous cortical activity, can be recognized and quantified. Here, we describe the experimental basis for interpreting these patterns and illustrate their translation to human disease. We further provide consensus recommendations for electrocorticographic methods to record, classify, and score spreading depolarizations and associated spreading depressions. These methods offer distinct advantages over other neuromonitoring modalities and allow for future refinement through less invasive and more automated approaches.

Published

2017

6. A high-performance application specific integrated circuit for electrical and neurochemical traumatic brain injury monitoring

Author

Pagkalos, I, Rogers, M, Boutelle, MG, Drakakis, EM, and Wellcome Trust

Subjects

0306 Physical Chemistry (incl. Structural), Traumatic Brain Injury, Science & Technology, Chemical Physics, Chemistry, Physical, Physics, CONTINUOUS ONLINE MICRODIALYSIS, Physics, Atomic, Molecular & Chemical, DEPRESSION, LACTATE, Neurophysiological Monitoring, GLUCOSE, Chemistry, Electricity, Physical Sciences, Brain Injuries, Traumatic, 0202 Atomic, Molecular, Nuclear, Particle and Plasma Physics, Application Specific Integrated Chip for Neurochemical Monitoring, Humans, 0307 Theoretical and Computational Chemistry, SPREADING DEPOLARIZATIONS, HUMAN CEREBRAL-CORTEX

Abstract

This paper presents the first application specific integrated chip (ASIC) for the monitoring of patients who have suffered a Traumatic Brain Injury (TBI). By monitoring the neuralphysiological (ECoG) and neurochemical (glucose, lactate and potassium) signals of the injured human brain tissue, it is possible to detect spreading depolarisations, which have been shown to be associated with poor TBI patient outcome. This paper describes the testing of a new 7.5mm2 ASIC fabricated in the commercially available AMS 0.35μm CMOS technology. The ASIC has been designed to meet the demands of processing the injured brain tissue's ECoG signals, recorded by means of depth or brain surface electrodes, and neurochemical signals, recorded using microdialysis coupled to microfluidics-based electrochemical biosensors. The potentiostats use switched-capacitor charge integration to record currents with 100fA resolution, and allow automatic gain changing to track the falling sensitivity of a biosensor. This work supports the idea of a "behind the ear" wireless microplatform modality, which could enable the monitoring of currently non-monitored mobile TBI patients for the onset of secondary brain injury.

Published

2018

7. Simultaneous monitoring of potassium, glucose and lactate during spreading depolarisation in the injured human brain - proof of principle of a novel real-time neurochemical analysis system, continuous online microdialysis (coMD)

Author

Rogers, ML, Leong, CL, Gowers, SAN, Samper, IC, Jewell, SL, Khan, A, McCarthy, L, Pahl, C, Tolias, CM, Walsh, DC, Strong, AJ, and Boutelle, MG

Subjects

Microdialysis, microfluidics, ENERGY-METABOLISM, Online Systems, Endocrinology & Metabolism, RELEVANCE, spreading depolarization, MALIGNANT STROKE, Humans, Lactic Acid, Coma, neurometabolic coupling, 1102 Cardiorespiratory Medicine and Haematology, SUBARACHNOID HEMORRHAGE, Science & Technology, Neurology & Neurosurgery, On-line microdialysis, ischaemic brain injury, Cortical Spreading Depression, Neurosciences, HEAD-INJURY, 1103 Clinical Sciences, Hematology, DEPRESSION, Neurophysiological Monitoring, NEUROINTENSIVE CARE, ISCHEMIA, Glucose, MIGRAINE, Brain Injuries, Potassium, Neurosciences & Neurology, Electrocorticography, HUMAN CEREBRAL-CORTEX, 1109 Neurosciences, Life Sciences & Biomedicine

Abstract

Spreading Depolarisations (SDs) occur spontaneously and frequently in injured human brain. They propagate slowly through injured tissue often cycling around a local area of damage. Tissue recovery after an SD requires greatly augmented energy utilisation to normalise ionic gradients from a virtually complete loss of membrane potential. In the injured brain this is difficult because local blood flow is often low and unreactive. In this study we use a new variant of microdialysis, continuous on-line microdialysis (coMD), to observe the effects of SDs on brain metabolism. The neurochemical changes are dynamic and take place on the timescale of the passage of an SD past the microdialysis probe. Dialysate potassium levels provide an ionic correlate of cellular depolarisation and show a clear transient increase. Dialysate glucose levels reflect a balance between local tissue glucose supply and utilization. These show a clear transient decrease of variable magnitude and duration. Dialysate lactate levels indicate non-oxidative metabolism of glucose and show a transient increase. Preliminary data suggest that the transient changes recover more slowly after the passage of a sequence of multiple SD’s giving rise to a decrease in basal dialysate glucose and an increase in basal dialysate potassium and lactate levels.

Published

2016