Your search keyword '"Dumont, Alexander"' showing total 7 results

1. A computationally efficient Monte‐Carlo model for biomedical Raman spectroscopy.

Author

Dumont, Alexander P., Fang, Qianqian, and Patil, Chetan A.

Abstract

Monte Carlo (MC) modeling is a valuable tool to gain fundamental understanding of light‐tissue interactions, provide guidance and assessment to optical instrument designs, and help analyze experimental data. It has been a major challenge to efficiently extend MC towards modeling of bulk‐tissue Raman spectroscopy (RS) due to the wide spectral range, relatively sharp spectral features, and presence of background autofluorescence. Here, we report a computationally efficient MC approach for RS by adapting the massively‐parallel Monte Carlo eXtreme (MCX) simulator. Simulation efficiency is achieved through "isoweight," a novel approach that combines the statistical generation of Raman scattered and Fluorescence emission with a lookup‐table‐based technique well‐suited for parallelization. The MC model uses a graphics processor to produce dense Raman and fluorescence spectra over a range of 800 − 2000 cm−1 with an approximately 100× increase in speed over prior RS Monte Carlo methods. The simulated RS signals are compared against experimentally collected spectra from gelatin phantoms, showing a strong correlation. [ABSTRACT FROM AUTHOR]

Published

2021

2. Clinical application of near infrared fiber optic spectroscopy for noninvasive bone assessment.

Author

Shanas, No'ad, Querido, William, Dumont, Alexander, Yonko, Elizabeth, Carter, Erin, Ok, Jina, Karchner, James P., Barbe, Mary F., Ali, Sayed, Patil, Chetan, Raggio, Cathleen, and Pleshko, Nancy

Abstract

Approaches for noninvasive bone quality assessment are of great clinical need, particularly in individuals that require close monitoring of disease progression. X‐ray measurements are standard approaches to assess bone quality; however, they have several disadvantages. Here, a nonionizing approach for noninvasive assessment of the second metacarpal bone based on near infrared (NIR) spectroscopy was investigated. Transcutaneous bone signal detection was experimentally confirmed with cadaveric hand data, and Monte Carlo modeling further indicated that 50% of the measured signals arise from bone. Spectral data were collected via a NIR fiber optic from the bone of individuals with osteogenesis imperfecta, a disease marked by frequent bone fractures and fragility. Multiple significant correlations were found between spectral parameters related to water, protein and fat, and standard bone quality parameters obtained by X‐ray measurements. The results from this preliminary study highlight the potential application of NIR spectroscopy for the noninvasive assessment of bone quality. [ABSTRACT FROM AUTHOR]

Published

2020

3. Development of Accelerated Raman Scattering and Fluorescent Monte Carlo Model.

Author

Dumont, Alexander P. and Patil, Chetan

Published

2017

4. Model-based characterization platform of fiber optic extended-wavelength diffuse reflectance spectroscopy for identification of neurovascular bundles.

Author

Sun, Yu, Dumont, Alexander P., Arefin, Mohammed Shahriar, and Patil, Chetan A.

Subjects

*REFLECTANCE spectroscopy, *FEMORAL nerve, *HYPERSPECTRAL imaging systems

Abstract

Significance: Fiber-optic extended-wavelength diffuse reflectance spectroscopy (EWDRS) using both visible/near-infrared and shortwave-infrared detectors enables improved detection of spectral absorbances arising from lipids, water, and collagen and has demonstrated promise in a variety of applications, including detection of nerves and neurovascular bundles (NVB). Development of future applications of EWDRS for nerve detection could benefit from the use of model-based analyses including Monte Carlo (MC) simulations and evaluation of agreement between model systems and empirical measurements. Aim: The aim of this work is to characterize agreement between EWDRS measurements and simulations and inform future applications of model-based studies of nerve-detecting applications. Approach: A model-based platform consisting of an ex vivo microsurgical nerve dissection model, unique two-layer optical phantoms, and MC model simulations of fiber-optic EWDRS spectroscopic measurements were used to characterize EWDRS and compare agreement across models. In addition, MC simulations of an EWDRS measurement scenario are performed to provide a representative example of future analyses. Results: EWDRS studies performed in the common chicken thigh femoral nerve microsurgical dissection model indicate similar spectral features for classification of NVB versus adjacent tissues as reported in porcine models and human subjects. A comparison of measurements from unique EWDRS issue mimicking optical phantoms and MC simulations indicates high agreement between the two in homogeneous and two-layer optical phantoms, as well as in dissected tissues. Finally, MC simulations of measurement over a simulated NVB indicate the potential of future applications for measurement of nerve plexus. Conclusions: Characterization of agreement between fiber-optic EWDRS measurements and MC simulations demonstrates strong agreement across a variety of tissues and optical phantoms, offering promise for further use to guide the continued development of EWDRS for translational applications. [ABSTRACT FROM AUTHOR]

Published

2022

5. Reducing racial bias in transcutaneous measurements with mobile phone camera based spatially resolved diffuse reflectance.

Author

Harrison-Smith, Brandon K., Arefin, Mohammed S., Dumont, Alexander, and Patil, Chetan

Published

2021

6. Monte Carlo based simulations of racial bias in pulse oximetry.

Author

Arefin, Mohammed Shahriar, Dumont, Alexander P., and Patil, Chetan A.

Published

2021

7. Development of a mobile phone camera-based transcutaneous bilirubinometer for low-resource settings.

Author

Harrison-Smith B, Dumont AP, Arefin MS, Sun Y, Lawal N, Dobson D, Nwaba A, Grossarth S, Paed AM, Farouk ZL, Weitkamp JH, and Patil CA

Abstract

Newborns in high-income countries are routinely screened for neonatal jaundice using transcutaneous bilirubinometery (TcB). In low-and middle-income countries, TcB is not widely used due to a lack of availability; however, mobile-phone approaches for TcB could help expand screening opportunities. We developed a mobile phone-based approach for TcB and validated the method with a 37 patient multi-ethnic pilot study. We include a custom-designed snap-on adapter that is used to create a spatially resolved diffuse reflectance detection configuration with the illumination provided by the mobile-phone LED flash. Monte-Carlo models of reflectance from neonatal skin were used to guide the design of an adapter for filtered red-green-blue (RGB) mobile-phone camera reflectance measurements. We extracted measures of reflectance from multiple optimized spatial-offset regions-of-interest (ROIs) and a linear model was developed and cross-validated. This resulted in a correlation between total serum bilirubin and mobile-phone TcB estimated bilirubin with a R 2 = 0.42 and Bland-Altman limits of agreement of +6.4 mg/dL to -7.0 mg/dL. These results indicate that a mobile phone with a modified adapter can be utilized to measure neonatal bilirubin values, thus creating a novel tool for neonatal jaundice screening in low-resource settings., Competing Interests: The authors declare that they have no conflict of interest., (Published by Optica Publishing Group under the terms of the Creative Commons Attribution 4.0 License. Further distribution of this work must maintain attribution to the author(s) and the published article’s title, journal citation, and DOI.)

Published

2022