Healthcare Technology Letters
Volume 1, Issue 1, March 2014
Volumes & issues:
Volume 1, Issue 1
March 2014
Editorial
- Author(s): Christopher J. James
- Source: Healthcare Technology Letters, Volume 1, Issue 1, page: 1 –1
- DOI: 10.1049/htl.2014.0056
- Type: Article
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When change happens: computer assistance and image guidance for minimally invasive therapy
- Author(s): Cristian A. Linte and Ziv Yaniv
- Source: Healthcare Technology Letters, Volume 1, Issue 1, p. 2 –5
- DOI: 10.1049/htl.2014.0058
- Type: Article
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Computer-assisted interventions are medical procedures that rely on image guidance and computer-based systems to provide visualisation and navigation information to the clinician, when direct vision of the sites or targets to be treated is not available, during minimally invasive procedures. Recent advances in medical image acquisition and processing, accompanied by technological breakthroughs in image fusion, visualisation and display have accelerated the adoption of minimally invasive approaches for a variety of medical procedures. This Letter is intended to serve as a brief overview of available image guidance and computer-assisted technology in the context of popular minimally invasive applications, while outlining some of the limitations and challenges in the transition from laboratory to clinical care.
Compressive sampling for time critical microwave imaging applications
- Author(s): Darren Craven ; Martin O'Halloran ; Brian McGinley ; Raquel C. Conceicao ; Liam Kilmartin ; Edward Jones ; Martin Glavin
- Source: Healthcare Technology Letters, Volume 1, Issue 1, p. 6 –12
- DOI: 10.1049/htl.2013.0043
- Type: Article
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Across all biomedical imaging applications, there is a growing emphasis placed on reducing data acquisition and imaging times. This research explores the use of a technique, known as compressive sampling or compressed sensing (CS), as an efficient technique to minimise the data acquisition time for time critical microwave imaging (MWI) applications. Where a signal exhibits sparsity in the time domain, the proposed CS implementation allows for sub-sampling acquisition in the frequency domain and consequently shorter imaging times, albeit at the expense of a slight degradation in reconstruction quality of the signals as the compression increases. This Letter focuses on ultra wideband (UWB) radar MWI applications where reducing acquisition is of critical importance therefore a slight degradation in reconstruction quality may be acceptable. The analysis demonstrates the effectiveness and suitability of CS with UWB applications.
Towards personalised management of atherosclerosis via computational models in vascular clinics: technology based on patient-specific simulation approach
- Author(s): Vanessa Díaz-Zuccarini ; Giulia Di Tomaso ; Obiekezie Agu ; Cesar Pichardo-Almarza
- Source: Healthcare Technology Letters, Volume 1, Issue 1, p. 13 –18
- DOI: 10.1049/htl.2013.0040
- Type: Article
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The development of a new technology based on patient-specific modelling for personalised healthcare in the case of atherosclerosis is presented. Atherosclerosis is the main cause of death in the world and it has become a burden on clinical services as it manifests itself in many diverse forms, such as coronary artery disease, cerebrovascular disease/stroke and peripheral arterial disease. It is also a multifactorial, chronic and systemic process that lasts for a lifetime, putting enormous financial and clinical pressure on national health systems. In this Letter, the postulate is that the development of new technologies for healthcare using computer simulations can, in the future, be developed as in-silico management and support systems. These new technologies will be based on predictive models (including the integration of observations, theories and predictions across a range of temporal and spatial scales, scientific disciplines, key risk factors and anatomical sub-systems) combined with digital patient data and visualisation tools. Although the problem is extremely complex, a simulation workflow and an exemplar application of this type of technology for clinical use is presented, which is currently being developed by a multidisciplinary team following the requirements and constraints of the Vascular Service Unit at the University College Hospital, London.
Towards enhancing the performance of multi-parameter patient monitors
- Author(s): V. Vaijeyanthi ; K. Vishnuprasad ; C. Santhosh Kumar ; K.I. Ramachandran ; R. Gopinath ; A. Anand Kumar ; Praveen Kumar Yadav
- Source: Healthcare Technology Letters, Volume 1, Issue 1, p. 19 –20
- DOI: 10.1049/htl.2013.0041
- Type: Article
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Multi-parameter patient monitors (MPMs) have become increasingly important in providing quality healthcare to patients. It is well known in the medical community that there exists an intrinsic relationship between different vital parameters in a healthy person, these include heart rate, blood pressure, respiration rate and oxygen saturation. For example, an increase in blood pressure would lead to a decrease in the heart rate, and vice versa. Although it is likely to improve the performance of MPM systems, this fact is not explored in engineering research. In this work, experiments show that deriving additional features to capture the intrinsic relationship between the vital parameters, the alarm accuracy (sensitivity), no-alarm accuracy (specificity) and the overall performance of MPMs can be improved. The geometric mean of the product of all the vital parameters taken in pairs of two was used to capture the intrinsic relationship between the different parameters. An improvement of 10.55% for sensitivity, 0.32% for specificity and an overall performance improvement of 1.03% was obtained, compared to the baseline system using classification and regression tree with the four vital parameters.
Multi-coil approach to reduce electromagnetic energy absorption for wirelessly powered implants
- Author(s): Anil Kumar RamRakhyani and Gianluca Lazzi
- Source: Healthcare Technology Letters, Volume 1, Issue 1, p. 21 –25
- DOI: 10.1049/htl.2013.0035
- Type: Article
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Near-field inductive coupling is a commonly used technique for wireless power transfer (WPT) in biomedical implants. Owing to the close proximity of the implant coil(s) with the tissue ( ∼1 mm) and high current ( ∼100–300 mA) in the magnetic coil(s), a significant induced electric field can be generated for the operating frequency (1–20 MHz). In this Letter, a multi-coil-based WPT technique is proposed to selectively control the currents in the external and implant coils to reduce the specific absorption rate (SAR). A three-coil WPT system, that can achieve 26% reduction in peak 1-g SAR and 15% reduction in peak 10-g SAR, as compared to a two-coil WPT system with the same dimensions, is implemented and used to demonstrate the effectiveness of the proposed approach. To achieve the seamless design for the external and implant electronics, the multi-coil system achieves the same voltage gain and bandwidth as the two-coil design with 46% improvement in the power transfer efficiency.
DCT domain feature extraction scheme based on motor unit action potential of EMG signal for neuromuscular disease classification
- Author(s): Abul Barkat Mollah Sayeed Ud Doulah ; Shaikh Anowarul Fattah ; Wei-Ping Zhu ; M. Omair Ahmad
- Source: Healthcare Technology Letters, Volume 1, Issue 1, p. 26 –31
- DOI: 10.1049/htl.2013.0036
- Type: Article
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A feature extraction scheme based on discrete cosine transform (DCT) of electromyography (EMG) signals is proposed for the classification of normal event and a neuromuscular disease, namely the amyotrophic lateral sclerosis. Instead of employing DCT directly on EMG data, it is employed on the motor unit action potentials (MUAPs) extracted from the EMG signal via a template matching-based decomposition technique. Unlike conventional MUAP-based methods, only one MUAP with maximum dynamic range is selected for DCT-based feature extraction. Magnitude and frequency values of a few high-energy DCT coefficients corresponding to the selected MUAP are used as the desired feature which not only reduces computational burden, but also offers better feature quality with high within-class compactness and between-class separation. For the purpose of classification, the K-nearest neighbourhood classifier is employed. Extensive analysis is performed on clinical EMG database and it is found that the proposed method provides a very satisfactory performance in terms of specificity, sensitivity and overall classification accuracy.
New approach for automatic classification of Alzheimer's disease, mild cognitive impairment and healthy brain magnetic resonance images
- Author(s): Salim Lahmiri and Mounir Boukadoum
- Source: Healthcare Technology Letters, Volume 1, Issue 1, p. 32 –36
- DOI: 10.1049/htl.2013.0022
- Type: Article
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Explored is the utility of modelling brain magnetic resonance images as a fractal object for the classification of healthy brain images against those with Alzheimer's disease (AD) or mild cognitive impairment (MCI). More precisely, fractal multi-scale analysis is used to build feature vectors from the derived Hurst's exponents. These are then classified by support vector machines (SVMs). Three experiments were conducted: in the first the SVM was trained to classify AD against healthy images. In the second experiment, the SVM was trained to classify AD against MCI and, in the third experiment, a multiclass SVM was trained to classify all three types of images. The experimental results, using the 10-fold cross-validation technique, indicate that the SVM achieved 97.08% ± 0.05 correct classification rate, 98.09% ± 0.04 sensitivity and 96.07% ± 0.07 specificity for the classification of healthy against MCI images, thus outperforming recent works found in the literature. For the classification of MCI against AD, the SVM achieved 97.5% ± 0.04 correct classification rate, 100% sensitivity and 94.93% ± 0.08 specificity. The third experiment also showed that the multiclass SVM provided highly accurate classification results. The processing time for a given image was 25 s. These findings suggest that this approach is efficient and may be promising for clinical applications.
Ultra-low-power wireless transmitter for neural prostheses with modified pulse position modulation
- Author(s): Farhad Goodarzy and Stan E. Skafidas
- Source: Healthcare Technology Letters, Volume 1, Issue 1, p. 37 –39
- DOI: 10.1049/htl.2013.0012
- Type: Article
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An ultra-low-power wireless transmitter for embedded bionic systems is proposed, which achieves 40 pJ/b energy efficiency and delivers 500 kb/s data using the medical implant communication service frequency band (402–405 MHz). It consumes a measured peak power of 200 µW from a 1.2 V supply while occupying an active area of 0.0016 mm2 in a 130 nm technology. A modified pulse position modulation technique called saturated amplified signal is proposed and implemented, which can reduce the overall and per bit transferred power consumption of the transmitter while reducing the complexity of the transmitter architectures, and hence potentially shrinking the size of the implemented circuitry. The design is capable of being fully integrated on single-chip solutions for surgically implanted bionic systems, wearable devices and neural embedded systems.
Straightforward and robust QRS detection algorithm for wearable cardiac monitor
- Author(s): M. Sabarimalai Manikandan and Barathram Ramkumar
- Source: Healthcare Technology Letters, Volume 1, Issue 1, p. 40 –44
- DOI: 10.1049/htl.2013.0019
- Type: Article
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This Letter presents a fairly straightforward and robust QRS detector for wearable cardiac monitoring applications. The first stage of the QRS detector contains a powerful ℓ1-sparsity filter with overcomplete hybrid dictionaries for emphasising the QRS complexes and suppressing the baseline drifts, powerline interference and large P/T waves. The second stage is a simple peak-finding logic based on the Gaussian derivative filter for automatically finding locations of R-peaks in the ECG signal. Experiments on the standard MIT-BIH arrythmia database show that the method achieves an average sensitivity of 99.91% and positive predictivity of 99.92%. Unlike existing methods, the proposed method improves detection performance under small-QRS, wide-QRS complexes and noisy conditions without using the searchback algorithms.
Temporal epilepsy seizures monitoring and prediction using cross-correlation and chaos theory
- Author(s): Tahar Haddad ; Naim Ben-Hamida ; Larbi Talbi ; Ahmed Lakhssassi ; Sadok Aouini
- Source: Healthcare Technology Letters, Volume 1, Issue 1, p. 45 –50
- DOI: 10.1049/htl.2013.0010
- Type: Article
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Temporal seizures due to hippocampal origins are very common among epileptic patients. Presented is a novel seizure prediction approach employing correlation and chaos theories. The early identification of seizure signature allows for various preventive measures to be undertaken. Electro-encephalography signals are spectrally broken down into the following sub-bands: delta; theta; alpha; beta; and gamma. The proposed approach consists of observing a high correlation level between any pair of electrodes for the lower frequencies and a decrease in the Lyapunov index (chaos or entropy) for the higher frequencies. Power spectral density and statistical analysis tools were used to determine threshold levels for the lower frequencies. After studying all five sub-bands, the analysis has revealed that the seizure signature can be extracted from the delta band and the high frequencies. High frequencies are defined as both the gamma band and the ripples occurring within the 60–120 Hz sub-band. To validate the proposed approach, six patients from both sexes and various age groups with temporal epilepsies originating from the hippocampal area were studied using the Freiburg database. An average seizure prediction of 30 min, an anticipation accuracy of 72%, and a false-positive rate of 0% were accomplished throughout 200 h of recording time.
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