Your search keyword '"Chitnis, Parag V."' showing total 12 results

1. Fast iterative reconstruction for photoacoustic tomography using learned physical model: Theoretical validation

Author

Hsu, Ko-Tsung, Guan, Steven, and Chitnis, Parag V.

Published

2023

2. Size-tunable ICG-based contrast agent platform for targeted near-infrared photoacoustic imaging.

Author

Singh, Shrishti, Giammanco, Giovanni, Hu, Chih-Hsiang, Bush, Joshua, Cordova, Leandro Soto, Lawrence, Dylan J., Moran, Jeffrey L., Chitnis, Parag V., and Veneziano, Remi

Published

2023

3. Distributed Wearable Ultrasound Sensors Predict Isometric Ground Reaction Force.

Author

King, Erica L., Patwardhan, Shriniwas, Bashatah, Ahmed, Magee, Meghan, Jones, Margaret T., Wei, Qi, Sikdar, Siddhartha, and Chitnis, Parag V.

Subjects

GROUND reaction forces (Biomechanics), VASTUS lateralis, VASTUS medialis, FEATURE extraction, ULTRASONIC imaging, RECTUS femoris muscles

Abstract

Rehabilitation from musculoskeletal injuries focuses on reestablishing and monitoring muscle activation patterns to accurately produce force. The aim of this study is to explore the use of a novel low-powered wearable distributed Simultaneous Musculoskeletal Assessment with Real-Time Ultrasound (SMART-US) device to predict force during an isometric squat task. Participants (N = 5) performed maximum isometric squats under two medical imaging techniques; clinical musculoskeletal motion mode (m-mode) ultrasound on the dominant vastus lateralis and SMART-US sensors placed on the rectus femoris, vastus lateralis, medial hamstring, and vastus medialis. Ultrasound features were extracted, and a linear ridge regression model was used to predict ground reaction force. The performance of ultrasound features to predict measured force was tested using either the Clinical M-mode, SMART-US sensors on the vastus lateralis (SMART-US: VL), rectus femoris (SMART-US: RF), medial hamstring (SMART-US: MH), and vastus medialis (SMART-US: VMO) or utilized all four SMART-US sensors (Distributed SMART-US). Model training showed that the Clinical M-mode and the Distributed SMART-US model were both significantly different from the SMART-US: VL, SMART-US: MH, SMART-US: RF, and SMART-US: VMO models (p < 0.05). Model validation showed that the Distributed SMART-US model had an R2 of 0.80 ± 0.04 and was significantly different from SMART-US: VL but not from the Clinical M-mode model. In conclusion, a novel wearable distributed SMART-US system can predict ground reaction force using machine learning, demonstrating the feasibility of wearable ultrasound imaging for ground reaction force estimation. [ABSTRACT FROM AUTHOR]

Published

2024

4. Comparing Deep Learning Frameworks for Photoacoustic Tomography Image Reconstruction

Author

Hsu, Ko-Tsung, Guan, Steven, and Chitnis, Parag V.

Published

2021

5. Limited-View and Sparse Photoacoustic Tomography for Neuroimaging with Deep Learning

Author

Guan, Steven, Khan, Amir A., Sikdar, Siddhartha, and Chitnis, Parag V.

Published

2020

6. NIR-II Nanoprobes: A Review of Components-Based Approaches to Next-Generation Bioimaging Probes.

Author

Dunn, Bryce, Hanafi, Marzieh, Hummel, John, Cressman, John R., Veneziano, Rémi, and Chitnis, Parag V.

Subjects

ACOUSTIC imaging, OPTICAL properties, CELL imaging, CONTRAST media, BIOFLUORESCENCE, INFRARED imaging, HUMAN facial recognition software, INFRARED absorption

Abstract

Fluorescence and photoacoustic imaging techniques offer valuable insights into cell- and tissue-level processes. However, these optical imaging modalities are limited by scattering and absorption in tissue, resulting in the low-depth penetration of imaging. Contrast-enhanced imaging in the near-infrared window improves imaging penetration by taking advantage of reduced autofluorescence and scattering effects. Current contrast agents for fluorescence and photoacoustic imaging face several limitations from photostability and targeting specificity, highlighting the need for a novel imaging probe development. This review covers a broad range of near-infrared fluorescent and photoacoustic contrast agents, including organic dyes, polymers, and metallic nanostructures, focusing on their optical properties and applications in cellular and animal imaging. Similarly, we explore encapsulation and functionalization technologies toward building targeted, nanoscale imaging probes. Bioimaging applications such as angiography, tumor imaging, and the tracking of specific cell types are discussed. This review sheds light on recent advancements in fluorescent and photoacoustic nanoprobes in the near-infrared window. It serves as a valuable resource for researchers working in fields of biomedical imaging and nanotechnology, facilitating the development of innovative nanoprobes for improved diagnostic approaches in preclinical healthcare. [ABSTRACT FROM AUTHOR]

Published

2023

7. Deep-Learning-Based Segmentation of Extraocular Muscles from Magnetic Resonance Images.

Author

Qureshi, Amad, Lim, Seongjin, Suh, Soh Youn, Mutawak, Bassam, Chitnis, Parag V., Demer, Joseph L., and Wei, Qi

Subjects

MAGNETIC resonance imaging, DEEP learning

Abstract

In this study, we investigated the performance of four deep learning frameworks of U-Net, U-NeXt, DeepLabV3+, and ConResNet in multi-class pixel-based segmentation of the extraocular muscles (EOMs) from coronal MRI. Performances of the four models were evaluated and compared with the standard F-measure-based metrics of intersection over union (IoU) and Dice, where the U-Net achieved the highest overall IoU and Dice scores of 0.77 and 0.85, respectively. Centroid distance offset between identified and ground truth EOM centroids was measured where U-Net and DeepLabV3+ achieved low offsets (p > 0.05) of 0.33 mm and 0.35 mm, respectively. Our results also demonstrated that segmentation accuracy varies in spatially different image planes. This study systematically compared factors that impact the variability of segmentation and morphometric accuracy of the deep learning models when applied to segmenting EOMs from MRI. [ABSTRACT FROM AUTHOR]

Published

2023

8. Fourier Neural Operator Network for Fast Photoacoustic Wave Simulations.

Author

Guan, Steven, Hsu, Ko-Tsung, and Chitnis, Parag V.

Subjects

ACOUSTIC imaging, DEEP learning, ROOT-mean-squares, THEORY of wave motion, COMPUTER vision

Abstract

Simulation tools for photoacoustic wave propagation have played a key role in advancing photoacoustic imaging by providing quantitative and qualitative insights into parameters affecting image quality. Classical methods for numerically solving the photoacoustic wave equation rely on a fine discretization of space and can become computationally expensive for large computational grids. In this work, we applied Fourier Neural Operator (FNO) networks as a fast data-driven deep learning method for solving the 2D photoacoustic wave equation in a homogeneous medium. Comparisons between the FNO network and pseudo-spectral time domain approach were made for the forward and adjoint simulations. Results demonstrate that the FNO network generated comparable simulations with small errors and was orders of magnitude faster than the pseudo-spectral time domain methods (~26× faster on a 64 × 64 computational grid and ~15× faster on a 128 × 128 computational grid). Moreover, the FNO network was generalizable to the unseen out-of-domain test set with a root-mean-square error of 9.5 × 10−3 in Shepp–Logan, 1.5 × 10−2 in synthetic vasculature, 1.1 × 10−2 in tumor and 1.9 × 10−2 in Mason-M phantoms on a 64 × 64 computational grid and a root mean squared of 6.9 ± 5.5 × 10−3 in the AWA2 dataset on a 128 × 128 computational grid. [ABSTRACT FROM AUTHOR]

Published

2023

9. Toward a wearable monitor of local muscle fatigue during electrical muscle stimulation using tissue Doppler imaging.

Author

Majdi, Joseph A., Acuña, Samuel A., Chitnis, Parag V., and Sikdar, Siddhartha

Subjects

ELECTRIC stimulation, WEARABLE technology, MUSCLE contraction, HUMAN-robot interaction, SKELETAL muscle

Abstract

Electrical muscle stimulation (EMS) is widely used in rehabilitation and athletic training to generate involuntary muscle contractions. However, EMS leads to rapid muscle fatigue, limiting the force a muscle can produce during prolonged use. Currently available methods to monitor localized muscle fatigue and recovery are generally not compatible with EMS. The purpose of this study was to examine whether Doppler ultrasound imaging can assess changes in stimulated muscle twitches that are related to muscle fatigue from electrical stimulation. We stimulated five isometric muscle twitches in the medial and lateral gastrocnemius of 13 healthy subjects before and after a fatiguing EMS protocol. Tissue Doppler imaging of the medial gastrocnemius recorded muscle tissue velocities during each twitch. Features of the average muscle tissue velocity waveforms changed immediately after the fatiguing stimulation protocol (peak velocity: -38%, p = .022; time-to-zero velocity: þ8%, p = .050). As the fatigued muscle recovered, the features of the average tissue velocity waveforms showed a return towards their baseline values similar to that of the normalized ankle torque. We also found that features of the average tissue velocity waveform could significantly predict the ankle twitch torque for each participant (R² = 0.255-0.849, p < .001). Our results provide evidence that Doppler ultrasound imaging can detect changes in muscle tissue during isometric muscle twitch that are related to muscle fatigue, fatigue recovery, and the generated joint torque. Tissue Doppler imaging may be a feasible method to monitor localized muscle fatigue during EMS in a wearable device. [ABSTRACT FROM AUTHOR]

Published

2022

10. SVD-Based Separation of Stable and Inertial Cavitation Signals Applied to Passive Cavitation Mapping During HIFU.

Author

Chitnis, Parag V., Farny, Caleb H., and Roy, Ronald A.

Subjects

*CAVITATION, *HIGH-intensity focused ultrasound, *SINGULAR value decomposition, *ACOUSTIC transducers, *RADIO frequency, *ULTRASONIC imaging

Abstract

Detection of inertial and stable cavitation is important for guiding high-intensity focused ultrasound (HIFU). Acoustic transducers can passively detect broadband noise from inertial cavitation and the scattering of HIFU harmonics from stable cavitation bubbles. Conventional approaches to cavitation noise diagnostics typically involve computing the Fourier transform of the time-domain noise signal, applying a custom comb filter to isolate the frequency components of interest, followed by an inverse Fourier transform. We present an alternative technique based on singular value decomposition (SVD) that efficiently separates the broadband emissions and HIFU harmonics. Spatiotemporally resolved cavitation detection was achieved using a 128-element, 5-MHz linear-array ultrasound imaging system operating in the receive mode at 15 frames/s. A 1.1-MHz transducer delivered HIFU to tissue-mimicking phantoms and excised liver tissue for a duration of 5 s. Beamformed radio frequency signals corresponding to each scan line in a frame were assembled into a matrix, and SVD was performed. Spectra of the singular vectors obtained from a tissue-mimicking gel phantom were analyzed by computing the peak ratio (${R}$), defined as the ratio of the peak of its fifth-order polynomial fit and the maximum spectral peak. Singular vectors that produced an ${R} < 0.048$ were classified as those representing stable cavitation, i.e., predominantly containing harmonics of HIFU. The projection of data onto this singular base reproduced stable cavitation signals. Similarly, singular vectors that produced an ${R} >0.2$ were classified as those predominantly containing broadband noise associated with inertial cavitation. These singular vectors were used to isolate the inertial cavitation signal. The ${R}$ -value thresholds determined using gel data were then employed to analyze cavitation data obtained from bovine liver ex vivo. The SVD-based method faithfully reproduced the structural details in the spatiotemporal cavitation maps produced using the more cumbersome comb-filter approach with a maximum root-mean-squared error of 10%. [ABSTRACT FROM AUTHOR]

Published

2019

11. Subharmonic Response of Polymer Contrast Agents Based on the Empirical Mode Decomposition.

Author

Hayashi, Rintaro, Allen, John S., Chitnis, Parag V., Mamou, Jonathan, and Ketterling, Jeffrey A.

Subjects

CONTRAST media, HILBERT-Huang transform, SUBHARMONIC functions, BACKSCATTERING, TIME series analysis

Abstract

The subharmonic threshold for ultrasound contrast agents has been defined as a 20–25 dB difference between the fundamental and subharmonic (2/1) spectral components of the backscatter signal. However, this Fourier-based criterion assumes a linear time-invariant signal. A more appropriate criterion for short cycle and frequency-modulated waveforms is proposed with an adaptive signal-processing approach based on the empirical mode decomposition (EMD) method. The signal is decomposed into an orthogonal basis known as intrinsic mode functions (IMFs) and a subharmonic threshold is defined with respect to the energy ratio of the subharmonic IMF component to that of the incident signal. The method is applied to backscatter data acquired from two polymer-shelled contrast agents, Philips (#38, mean diameter 2.0 \mu \textm ) and Point Biomedical (#12027, mean diameter 3.9 \mu \textm ). The acoustic backscatter signals are investigated for a single contrast agent subjected to monofrequency (20 MHz, 20 cycles) and chirp (15–25 MHz, 20 cycles) forcing for incident pressures ranging from 0.5 to 2.4 MPa. In comparison to the spectral peak difference (20 dB) criterion, the EMD method is more sensitive in determining subharmonic signals. [ABSTRACT FROM PUBLISHER]

Published

2016

12. An implantable compound-releasing capsule triggered on demand by ultrasound.

Author

Ordeig, Olga, Chin, Sau Yin, Kim, Sohyun, Chitnis, Parag V., and Sia, Samuel K.

Published

2016