Your search keyword '"Vali, Kourosh"' showing total 3 results

1. BASS: Safe Deep Tissue Optical Sensing for Wearable Embedded Systems

Author

Vali, Kourosh, Vafi, Ata, Kasap, Begum, and Ghiasi, Soheil

Subjects

Engineering, Electronics, Sensors and Digital Hardware, Bioengineering, Affordable and Clean Energy, Medical cyber-physical systems, design space exploration, multi-objective optimization, wearable embedded systems, deep tissue optical sensing, internet of medical things, medical cyber-physical systems, Computer Software, Distributed Computing, Computer Hardware, Computer Hardware & Architecture, Communications engineering, Distributed computing and systems software

Abstract

In wearable optical sensing applications whose target tissue is not superficial, such as deep tissue oximetry, the task of embedded system design has to strike a balance between two competing factors. On one hand, the sensing task is assisted by increasing the radiated energy into the body, which in turn, improves the signal-to-noise ratio (SNR) of the deep tissue at the sensor. On the other hand, patient safety consideration imposes a constraint on the amount of radiated energy into the body. In this paper, we study the trade-offs between the two factors by exploring the design space of the light source activation pulse. Furthermore, we propose BASS, an algorithm that leverages the activation pulse design space exploration, which further optimizes deep tissue SNR via spectral averaging, while ensuring the radiated energy into the body meets a safe upper bound. The effectiveness of the proposed technique is demonstrated via analytical derivations, simulations, and in vivo measurements in both pregnant sheep models and human subjects.

Published

2023

2. BASS: Safe Deep Tissue Optical Sensing forWearable Embedded Systems.

Author

VALI, KOUROSH, VAFI, ATA, KASAP, BEGUM, and GHIASI, SOHEIL

Subjects

LIGHT sources, TISSUES, SYSTEMS design, PATIENT safety, OXIMETRY

Abstract

In wearable optical sensing applications whose target tissue is not superficial, such as deep tissue oximetry, the task of embedded system design has to strike a balance between two competing factors. On one hand, the sensing task is assisted by increasing the radiated energy into the body, which in turn, improves the signalto-noise ratio (SNR) of the deep tissue at the sensor. On the other hand, patient safety consideration imposes a constraint on the amount of radiated energy into the body. In this paper, we study the trade-offs between the two factors by exploring the design space of the light source activation pulse. Furthermore, we propose BASS, an algorithm that leverages the activation pulse design space exploration, which further optimizes deep tissue SNR via spectral averaging, while ensuring the radiated energy into the body meets a safe upper bound. The effectiveness of the proposed technique is demonstrated via analytical derivations, simulations, and in vivo measurements in both pregnant sheep models and human subjects. [ABSTRACT FROM AUTHOR]

Published

2023

3. Optode Design Space Exploration for Clinically-robust Non-invasive Fetal Oximetry.

Author

FONG, DANIEL D., SRINIVASAN, VIVEK J., VALI, KOUROSH, and GHIASI, SOHEIL

Subjects

OXIMETRY, FETAL tissues, LIGHT sources, PREGNANT women, PHOTODETECTORS

Abstract

Non-invasive transabdominal fetal oximetry (TFO) has the potential to improve delivery outcomes by providing physicians with an objective metric of fetal well-being during labor. Fundamentally, the technology is based on sending light through the maternal abdomen to investigate deep fetal tissue, followed by detection and processing of the light that returns (via scattering) to the outside of the maternal abdomen. The placement of the photodetector in relation to the light source critically impacts TFO system performance, including its operational robustness in the face of fetal depth variation. However, anatomical differences between pregnant women cause the fetal depths to vary drastically, which further complicates the optical probe (optode) design optimization. In this paper, we present a methodology to solve this problem. We frame optode design space exploration as a multi-objective optimization problem, where hardware complexity (cost) and performance across a wider patient population (robustness) form competing objectives. We propose a model-based approach to characterize the Pareto-optimal points in the optode design space, through which a specific design is selected. Experimental evaluation via simulation and in vivo measurement on pregnant sheep support the efficacy of our approach. [ABSTRACT FROM AUTHOR]

Published

2019