Marggie Jones scite author profile

Electromagnetic (EM) medical technologies are rapidly expanding worldwide for both diagnostics and therapeutics. As these technologies are low-cost and minimally invasive, they have been the focus of significant research efforts in recent years. Such technologies are often based on the assumption that there is a contrast in the dielectric properties of different tissue types or that the properties of particular tissues fall within a defined range. Thus, accurate knowledge of the dielectric properties of biological tissues is fundamental to EM medical technologies. Over the past decades, numerous studies were conducted to expand the dielectric repository of biological tissues. However, dielectric data is not yet available for every tissue type and at every temperature and frequency. For this reason, dielectric measurements may be performed by researchers who are not specialists in the acquisition of tissue dielectric properties. To this end, this paper reviews the tissue dielectric measurement process performed with an open-ended coaxial probe. Given the high number of factors, including equipment- and tissue-related confounders, that can increase the measurement uncertainty or introduce errors into the tissue dielectric data, this work discusses each step of the coaxial probe measurement procedure, highlighting common practices, challenges, and techniques for controlling and compensating for confounders.

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Gamma Band Neural Stimulation in Humans and the Promise of a New Modality to Prevent and Treat Alzheimer’s Disease

McDermott

Porter

Hughes

et al. 2018

JAD

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Existing treatments for Alzheimer’s disease (AD) have questionable efficacy with a need for research into new and more effective therapies to both treat and possibly prevent the condition. This review examines a novel therapeutic modality that shows promise for treating AD based on modulating neuronal activity in the gamma frequency band through external brain stimulation. The gamma frequency band is roughly defined as being between 30 Hz-100 Hz, with the 40 Hz point being of particular significance. The epidemiology, diagnostics, existing pathological models, and related current treatment targets are initially briefly reviewed. Next, the concept of external simulation triggering brain activity in the gamma band with potential demonstration of benefit in AD is introduced with reference to a recent important study using a mouse model of the disease. The review then presents a selection of relevant studies that describe the neurophysiology involved in brain stimulation by external sources, followed by studies involving application of the modality to clinical scenarios. A table summarizing the results of clinical studies applied to AD patients is also reported and may aid future development of the modality. The use of a therapy based on modulation of gamma neuronal activity represents a novel non-invasive, non-pharmacological approach to AD. Although use in clinical scenarios is still a relatively recent area of research, the technique shows good signs of efficacy and may represent an important option for treating AD in the future.

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Gamma Band Light Stimulation in Human Case Studies: Groundwork for Potential Alzheimer’s Disease Treatment

Jones

McDermott

Oliveira

et al. 2019

JAD

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Background: It is known that proteins associated with Alzheimer's disease (AD) pathogenesis are significantly reduced by 40 Hz entrainment in mice. If this were to translate to humans, verifying that such a light stimulus can induce a 40 Hz entrainment response in humans and harnessing insights from these case studies could be one step in the development of a multisensory device to prevent and treat AD. Objective: Verify the inducement of a 40 Hz response in the human brain by a 40 Hz light stimulus and obtain insights that could potentially aid in the development of a multisensory device for the prevention and treatment of AD. Methods: Electroencephalographic brain activity was recorded simultaneously with application of stimulus at different frequencies and intensities. Power spectral densities were analyzed. Results: Entrainment to visual stimuli occurred with the largest response at 40 Hz. The high intensity 40 Hz stimulus caused widespread entrainment. The number of electrodes demonstrating entrainment increased with increasing light intensity. Largest amplitudes for the high intensity 40 Hz stimulus were consistently found at the primary visual cortex. There was a harmonic effect at double the frequency for the 40 Hz stimulus. An eyes-open protocol caused more entrainment than an eyes-closed protocol. Conclusion: It was possible to induce widespread entrainment using a 40 Hz light stimulus in this sample cohort. Insights gleaned from these case studies could potentially aid in the development of a multisensory medical device to prevent and treat AD.

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Stable tissue-mimicking materials and an anatomically realistic, adjustable head phantom for electrical impedance tomography

McDermott

McGinley

Krukiewicz

et al. 2017

Biomed. Phys. Eng. Express

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To develop dielectrically accurate, easy to mould solid tissue-mimicking materials (TMMs) for use with electrical impedance tomography and combine them into a head phantom with realistic anatomy and adjustable pathological lesions. Methods: The conductivity profiles of fat and blood, which span those of most biological tissues, along with aggregate models of the tissues of the head external to the brain, the tissues of the brain, and the cerebellum are identified across the 1 kHz -1 MHz band. TMM mixtures made from polyurethane, graphite, carbon black and either acetone or isopropanol are fabricated to emulate the conductivity profiles of the reference tissues. 3Dprinted anatomically realistic moulds of the head and brain are used to cast a two-layer head and brain phantom with cylindrical holes left to allow addition of phantom pathological lesions such as haemorrhages. Results: The tissue-mimicking material spans a wide biological range of fat to blood and is adjustable to match any target tissue. Uniquely, the material is mechanically stable and easy to mould. The fabricated head phantom has excellent anatomic realism, and can represent a healthy brain or one with pathological lesions. The added lesions are easy to adjust in terms of size, shape, and material properties. Conclusion: The presented TMMs can be used to fabricate realistic phantoms for use in electrical impedance tomography studies of most tissue sets. Significance: These tissue-mimicking materials are an important development in phantom technology for electrical impedance tomography; the sample head phantom demonstrates the value and flexibility of the TMMs.

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Symmetry difference electrical impedance tomography—a novel modality for anomaly detection

McDermott

Porter²,

Jones³

et al. 2018

Physiol. Meas.

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Marggie Jones

Open-Ended Coaxial Probe Technique for Dielectric Measurement of Biological Tissues: Challenges and Common Practices

Gamma Band Neural Stimulation in Humans and the Promise of a New Modality to Prevent and Treat Alzheimer’s Disease

Gamma Band Light Stimulation in Human Case Studies: Groundwork for Potential Alzheimer’s Disease Treatment

Stable tissue-mimicking materials and an anatomically realistic, adjustable head phantom for electrical impedance tomography

Symmetry difference electrical impedance tomography—a novel modality for anomaly detection

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