Bindu Gopinathan Nair scite author profile

Medical imaging has recently expanded into the dual- or multi-modality fusion of anatomical and functional imaging modalities. This significantly improves the diagnostic power while simultaneously increasing the cost of an already expensive medical devices or investigations and decreasing their mobility. We are introducing a novel imaging concept of four-dimensional (4D) Microwave Tomographic (MWT) functional imaging: three-dimensional (3D) in spatial domain plus one-dimension (1D) in the time, functional dynamic domain. Instead of a fusion of images obtained by different imaging modalities, 4D MWT fuses absolute anatomical images with dynamic, differential images of the same imaging technology. The approach was successively validated in animal experiments with short term arterial flow reduction and a simulated compartment syndrome in an initial simplified experimental setting using dedicated microwave tomographic system. The presented fused images are not perfect as MWT is a novel imaging modality at its early stage of the development and ways of reading of reconstructed MWT images need to be further studied and understood. However, the reconstructed fused images present clear evidence that microwave tomography is an emerging imaging modality with great potentials for functional imaging.

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Microwave tomography of extremities: 1. Dedicated 2D system and physiological signatures

Semenov

Kellam

Sizov

et al. 2011

Phys. Med. Biol.

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Microwave Tomography (MWT) is a novel imaging modality which might be applicable for non-invasive assessment of functional and pathological conditions of biological tissues. The imaging of the soft tissue of extremities is one of its potential applications. The feasibility of this technology for such applications was demonstrated earlier. This is the first of two companion papers focused on an application of MWT for imaging of the extremity’s soft tissues. The goal of this study is to assess the technical performance of the developed 2D MWT system dedicated for imaging of functional and pathological conditions of the extremity’s soft tissues. Specifically, the system’s performance was tested by its ability to detect signals associated with physiological activity and soft tissue interventions (circulatory related changes, blood flow reduction and a simulated compartmental syndrome) – so called “physiological signatures”. The developed 2D MWT system dedicated for an imaging of animal extremities demonstrates good technical performance allowing for stable and predictable data acquisition with reasonable agreement between experimentally measured electromagnetic (EM) field and simulated EM field within a measurement domain. Using the system we were able to obtain physiological signatures associated with systolic vs diastolic phases of circulation in an animal extremity, reperfusion vs occlusion phases of the blood supply to the animal’s extremity and the a compartment syndrome. The imaging results are presented and discussed in the second companion paper.

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Low temperature thermopower and electrical conductivity in highly conductive CuInO₂thin films

Nair¹,

Okram

Naduvath

et al. 2014

J. Mater. Chem. C

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Highly conductive n- and p-type CuInO thin films by reactive evaporation

Mary¹,

Nair²,

Naduvath

et al. 2014

Journal of Alloys and Compounds

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Band structure and diode characteristics of transparent pn-homojunction using delafossite CuInO₂

Rahman¹,

Esthan²,

Nair³

et al. 2019

J. Phys. D: Appl. Phys.

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Technologically relevant highly rectifying all transparent delafossite pn homojunctions with CuInO 2 as n-type layer and Ca doped CuInO 2 as p-type layer are fabricated by oxygen plasma assisted thermal evaporation method. The best diode gives a forward to reverse current ratio ~619, which is about 62 times than that reported to date in a delafossite pn homojunction, with an ideality factor of 2.42 and a cut-in voltage of 0.87 V. Optical transmittance is 50%-70% in the visible region. Junction capacitance is in picoFarads and it is independent of frequency in the range 2 kHz to 2 MHz at a reverse voltage of 5 V. The band structure of the transparent delafossite diode is deduced for the first time by a combined analysis of the valence band spectra from x-ray photoelectron spectroscopy and the optical data.

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