Showing total 5 results

1. Multi-Frequency Electromagnetic Tomography for Acute Stroke Detection Using Frequency-Constrained Sparse Bayesian Learning.

Author

Xiang, Jinxi, Dong, Yonggui, and Yang, Yunjie

Subjects

MAGNETIC induction tomography, STROKE, IMAGE reconstruction, DISTRIBUTION (Probability theory)

Abstract

Imaging the bio-impedance distribution of the brain can provide initial diagnosis of acute stroke. This paper presents a compact and non-radiative tomographic modality, i.e. multi-frequency Electromagnetic Tomography (mfEMT), for the initial diagnosis of acute stroke. The mfEMT system consists of 12 channels of gradiometer coils with adjustable sensitivity and excitation frequency. To solve the image reconstruction problem of mfEMT, we propose an enhanced Frequency-Constrained Sparse Bayesian Learning (FC-SBL) to simultaneously reconstruct the conductivity distribution at all frequencies. Based on the Multiple Measurement Vector (MMV) model in the Sparse Bayesian Learning (SBL) framework, FC-SBL can recover the underlying distribution pattern of conductivity among multiple images by exploiting the frequency constraint information. A realistic 3D head model was established to simulate stroke detection scenarios, showing the capability of mfEMT to penetrate the highly resistive skull and improved image quality with FC-SBL. Both simulations and experiments showed that the proposed FC-SBL method is robust to noisy data for image reconstruction problems of mfEMT compared to the single measurement vector model, which is promising to detect acute strokes in the brain region with enhanced spatial resolution and in a baseline-free manner. [ABSTRACT FROM AUTHOR]

Published

2020

2. Automated Scoring of Hemiparesis in Acute Stroke From Measures of Upper Limb Co-Ordination Using Wearable Accelerometry.

Author

Datta, Shreyasi, Karmakar, Chandan K., Rao, Aravinda S., Yan, Bernard, and Palaniswami, Marimuthu

Subjects

HEMIPARESIS, ACCELEROMETRY, STROKE, ARM, UNITS of measurement, NEUROLOGICAL disorders

Abstract

Stroke survivors usually experience paralysis in one half of the body, i.e., hemiparesis, and the upper limbs are severely affected. Continuous monitoring of hemiparesis progression hours after the stroke attack involves manual observation of upper limb movements by medical experts in the hospital. Hence it is resource and time intensive, in addition to being prone to human errors and inter-rater variability. Wearable devices have found significance in automated continuous monitoring of neurological disorders like stroke. In this paper, we use accelerometer signals acquired using wrist-worn devices to analyze upper limb movements and identify hemiparesis in acute stroke patients, while they perform a set of proposed spontaneous and instructed movements. We propose novel measures of time (and frequency) domain coherence between accelerometer data from two arms at different lags (and frequency bands). These measures correlate well with the clinical gold standard of measurement of hemiparetic severity in stroke, the National Institutes of Health Stroke Scale (NIHSS). The study, undertaken on 32 acute stroke patients with varying levels of hemiparesis and 15 healthy controls, validates the use of short length (< 10 minutes) accelerometry data to identify hemiparesis through leave-one-subject-out cross-validation based hierarchical discriminant analysis. The results indicate that the proposed approach can distinguish between controls, moderate and severe hemiparesis with an average accuracy of 91%. [ABSTRACT FROM AUTHOR]

Published

2020

3. e-ASPECTS for early detection and diagnosis of ischemic stroke

Author

Touati Haifa, Boughariou Jihene, Ben Hamida Ahmed, and Sellemi Lamia

Subjects

medicine.medical_specialty, medicine.diagnostic_test, business.industry, Early detection, Computed tomography, medicine.disease, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Physical medicine and rehabilitation, Neuroimaging, Ischemic stroke, medicine, cardiovascular diseases, business, Stroke, 030217 neurology & neurosurgery, Acute stroke

Abstract

Ischemic Stroke is one of the major causes of human death and disability. So early stroke diagnosis is vital for patient’s survival and is remained as challenge for neurophysicians. The electronic Alberta Stroke Program Early CT Score (e-ASPECTS) software is widely used by neurophysician to assess the extent of early ischemic changes in brain imaging for acute stroke treatment. However, despite its efficiency, e-ASPECTS suffer of some limitations because of non-contrast computed-tomography scans. This study aims to present the e-ASPECTS program limits of through a literature review of recent studies that compare between automatic performance and human performance at the level of stroke detection and assessment. The present paper highlights the recently developed Artificial-Intelligent based tools in diagnosis and treatment of stroke with a comparison with humain score.

Published

2020

4. Point-of-care neurophysiology: Assessing neural function in the acute stroke patient

Author

Jonathan A. Norton, Francis M. Bui, and Andrew R. Kostiuk

Subjects

medicine.medical_specialty, business.industry, Commodity hardware, Control (management), Real-time computing, Cloud computing, Neurophysiology, Clinical neurophysiology, Risk analysis (engineering), Neural function, Medicine, business, Acute stroke, Point of care

Abstract

Assessing the neural function in acute stroke patients in a timely manner is important to identify time sensitive treatment. While a hospital may have clinical neurophysiology machines, these are complex to use and crucially expensive to own. A low-cost point-of-care system for assessing the neural function in such patients would have value in many clinical centers, and also potentially with EMS teams. A study to determine the effectiveness of such an approach, especially with a limited number of EEG channels, requires suitable devices to provide this functionality. This paper focuses on the design and performance considerations for such a system which will be used in this study. Of interest is the use of the devices the clinicians already have (e.g. smartphone, tablet) to access and control the system as well as real-time performance of sampling on low-cost commodity hardware and the provision of an extensible platform that can be upgraded and take advantage of cloud computing resources.

Published

2016

5. Case study of patients participating in a randomised controlled trial of upper-limb robotic rehabilitation in acute stroke services

Author

Andrew Jackson, J. A. Cozens, Sophie Makower, Rory J O’Connor, and Martin Levesley

Subjects

medicine.medical_specialty, Weakness, business.industry, Robotic rehabilitation, National health service, law.invention, medicine.anatomical_structure, Physical medicine and rehabilitation, Randomized controlled trial, law, Physical therapy, Medicine, Upper limb, In patient, sense organs, medicine.symptom, skin and connective tissue diseases, Rehabilitation robotics, business, Acute stroke

Abstract

This paper presents some findings from a randomised controlled trial in patients with upper-limb weakness in acute stroke services within the UK's National Health Service. Three patients were selected from the robot arm of the trial; one who exhibited a large increase in Fugl-Meyer score (change > 30); one who exhibited a moderate change (10 < change < 20) and a subject who demonstrated no change between baseline and follow-up. The results from robot assistance level and target achievement over the course of the treatment are presented for the three patients, demonstrating the system's ability to automatically alter the assistance level as patients progress.

Published

2015