Affiliations: ​
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Tandon School of Engineering, New York University (2023-Present)
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Weill Cornell Medicine (2022-2023)- Fellow in Radiology (Non ACGME)
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InGenuyX Engineering Solutions (2022- 2023) - Engineering Consultant
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University of Texas at San Antonio, MeMDRL Lab (2018-2022)- Graduate Research Assistant
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Central Michigan University, IoT Lab (2017-2018)- Graduate Research Assistant
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Central Michigan University, Electroporation Lab (2016-2018)- Graduate Research Assistant
Memberships:
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International Society for Magnetic Resonance in Medicine (ISMRM)- Trainee Member.
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Texas Board of Professional Engineers and Land Surveyors - Engineer -In -Training
Shadeeb Hossain
Shadeeb Hossain is an Electrical, Electronics and Computer Engineer and his area of expertise is (i) Electromagnetism, (ii) Smart materials and (iii) Optics/ Photonics with primary focus on biomedical applications.
He is a registered Engineer-In-Training (Texas Board of Professional Engineers and Land Surveyors), and a Certified Cloud Practitioner (Amazon CCP).
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Educational Background:
PhD in Electrical Engineering,
The University of Texas at San Antonio, San Antonio, TX USA
M.Sc. in Electrical Engineering,
Central Michigan University, Mount Pleasant, MI, USA.
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MBA in Finance
University of Dhaka, Dhaka, Bangladesh
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Skills: Finite Element Analysis, Computational Modeling, Quantitative Analysis, Material Property Analysis, Optical Property Analysis and Plasma Properties of biological cells.
Software: COMSOL Multiphysics, MATLAB, C++, Python, LABVIEW, and GROMACS.
Hardware: (i) Photoacoustic Tomographic Imaging System, (ii) Network Analyzer (iii) FTIR Spectroscopy (iv) UV Spectrometer (v) Raspberry Pi, and (vii) associated IoT sensor connectivity module (between Wireless sensors, Raspberry Pi and ThingSpeak).
Opto-Magneto-Electric Properties of Cobalt Ferrite-Barium Titanate Core-Shell Nanoparticles for inducing Nano-electroporation
Recent Projects
Plasma and Optical Properties to diagnose cancer cells
Computational Modelling to study Membrane Permeability due to Synergistic Effect of Controlled Shock wave and Electric Field Application
Hardware Requirements for 2D Cylindrical-High Pass Ladder Coil Design enabling Homogeneous Excitation in Ultra High-Field MRI
Recent Publication(s)
Cobalt Ferrite Barium-Titanate core-shell nanoparticle has shown application in targeted drug delivery via an external magnetic field. This paper focuses on the absorption peak in the Infrared region of the aforementioned core-shell nanoparticles that can allow scope for application in photo simulation or triggering drug release at a specific absorption band. FTIR was used to verify the absorption peak for 50 nm Cobalt ferrite nanoparticles, Cobalt Ferrite Barium Titanate core-shell nanoparticles of 50- 50 composition, and barium titanate. The absorption peak was obtained at 2893 nm, 2850 nm, and 2930 nm respectively. The shift was due to the inherent chemical bonds and dielectric properties. The results for absorption peak were verified with Finite Element Analysis using a simulation tool, COMSOL. The results followed a general trend and the absorption peaks were at 2150 nm, 2350 nm, and 2400 nm respectively. Also, the shift in resonance peak for cobalt ferrite and its core-shell with barium titanate was compared with the cavity perturbation technique in the microwave frequency range. It was realized that the shift in resonance mode, quality factor, and loss tangent was slightly higher for core-shell due to the damping effect induced by the difference in optical and dielectric properties
S. Hossain, V. Taracila, F. J. L. Robb, J. Moore and S. A. Winkler, "Hardware Requirements for 2D Cylindrical-High Pass Ladder Coil Design enabling Homogeneous Excitation in Ultra High-Field MRI," 2023 IEEE Symposium on Industrial Electronics & Applications (ISIEA), Kuala Lumpur, Malaysia, 2023, pp. 1-4, doi: 10.1109/ISIEA58478.2023.10212268.
S. Hossain and S. Hossain, "Optical Characterization of Cobalt Ferrite and Magnetoelectric Cobalt Ferrite-Barium Titanate Core-Shell Nanoparticles in Infra-Red Range," in IEEE Transactions on Nanotechnology,
doi: 10.1109/TNANO.2022.3160349.
Abstract:
Abstract—This paper discusses the hardware architecture of a volumetric 2D c-HPL radio frequency MRI coil. Five prototypes using different inductor-capacitor (LC) resonator combinations are constructed. The experimentally obtained eigenfrequencies are compared with those obtained theoretically from the dispersion equation. The transverse and longitudinal coupling coefficients are approximately 6% and 9%, respectively. An individual element consisting of 12 pF capacitors at each end and a simple tunable non-magnetic variable capacitor resulted in a single-element resonance frequency, f, of 286 MHz. For a 4 x 6 array with this individual resonance, the experimentally obtained, coupled, eigenfrequencies were measured as 274.17 MHz, 276.98 MHz, 280.2 MHz, 283.82 MHz, 286.63 MHz, 296.68 MHz (imaging mode), and 305 MHz, which is in good agreement with the dispersion equation