Literature DB >> 31312668

Effects of the instrument response function and the gate width in time-domain diffuse correlation spectroscopy: model and validations.

Lorenzo Colombo1, Marco Pagliazzi2, Sanathana Konugolu Venkata Sekar1, Davide Contini1, Alberto Dalla Mora1, Lorenzo Spinelli3, Alessandro Torricelli1,3, Turgut Durduran2,4, Antonio Pifferi1,3.   

Abstract

Time-domain diffuse correlation spectroscopy (TD-DCS) is an emerging noninvasive optical technique with the potential to resolve blood flow (BF) and optical coefficients (reduced scattering and absorption) in depth. Here, we study the effects of finite temporal resolution and gate width in a realistic TD-DCS experiment. We provide a model for retrieving the BF from gated intensity autocorrelations based on the instrument response function, which allows for the use of broad time gates. This, in turn, enables a higher signal-to-noise ratio that is critical for in vivo applications. In numerical simulations, the use of the proposed model reduces the error in the estimated late gate BF from 34% to 3%. Simulations are also performed for a wide set of optical properties and source-detector separations. In a homogeneous phantom experiment, the discrepancy between later gates BF index and ungated BF index is reduced from 37% to 2%. This work not only provides a tool for data analysis but also physical insights, which can be useful for studying and optimizing the system performance.

Entities:  

Keywords:  blood flow; diffuse optics; time-resolved imaging

Year:  2019        PMID: 31312668      PMCID: PMC6624407          DOI: 10.1117/1.NPh.6.3.035001

Source DB:  PubMed          Journal:  Neurophotonics        ISSN: 2329-423X            Impact factor:   3.593


  18 in total

1.  Deconvolution method for recovering the photon time-of-flight distribution from time-resolved measurements.

Authors:  Mamadou Diop; Keith St Lawrence
Journal:  Opt Lett       Date:  2012-06-15       Impact factor: 3.776

2.  Diffusing wave spectroscopy.

Authors: 
Journal:  Phys Rev Lett       Date:  1988-03-21       Impact factor: 9.161

3.  Reflectance-mode interferometric near-infrared spectroscopy quantifies brain absorption, scattering, and blood flow index in vivo.

Authors:  Dawid Borycki; Oybek Kholiqov; Vivek J Srinivasan
Journal:  Opt Lett       Date:  2017-02-01       Impact factor: 3.776

4.  Diffuse Optics for Tissue Monitoring and Tomography.

Authors:  T Durduran; R Choe; W B Baker; A G Yodh
Journal:  Rep Prog Phys       Date:  2010-07

5.  In vivo time-gated diffuse correlation spectroscopy at quasi-null source-detector separation.

Authors:  M Pagliazzi; S Konugolu Venkata Sekar; L Di Sieno; L Colombo; T Durduran; D Contini; A Torricelli; A Pifferi; A Dalla Mora
Journal:  Opt Lett       Date:  2018-06-01       Impact factor: 3.776

6.  Time domain diffuse correlation spectroscopy with a high coherence pulsed source: in vivo and phantom results.

Authors:  M Pagliazzi; S Konugolu Venkata Sekar; L Colombo; E Martinenghi; J Minnema; R Erdmann; D Contini; A Dalla Mora; A Torricelli; A Pifferi; T Durduran
Journal:  Biomed Opt Express       Date:  2017-10-27       Impact factor: 3.732

7.  Analytical models for time-domain diffuse correlation spectroscopy for multi-layer and heterogeneous turbid media.

Authors:  Jun Li; Lina Qiu; Chien-Sing Poon; Ulas Sunar
Journal:  Biomed Opt Express       Date:  2017-11-09       Impact factor: 3.732

8.  Liquid phantoms for near-infrared and diffuse correlation spectroscopies with tunable optical and dynamic properties.

Authors:  Lorenzo Cortese; Giuseppe Lo Presti; Marco Pagliazzi; Davide Contini; Alberto Dalla Mora; Antonio Pifferi; Sanathana Konugolu Venkata Sekar; Lorenzo Spinelli; Paola Taroni; Marta Zanoletti; Udo M Weigel; Sixte de Fraguier; An Nguyen-Dihn; Bogdan Rosinski; Turgut Durduran
Journal:  Biomed Opt Express       Date:  2018-04-04       Impact factor: 3.732

9.  Time domain diffuse correlation spectroscopy: modeling the effects of laser coherence length and instrument response function.

Authors:  Xiaojun Cheng; Davide Tamborini; Stefan A Carp; Oleg Shatrovoy; Bernhard Zimmerman; Danil Tyulmankov; Andrew Siegel; Megan Blackwell; Maria Angela Franceschini; David A Boas
Journal:  Opt Lett       Date:  2018-06-15       Impact factor: 3.776

10.  FoCuS-point: software for STED fluorescence correlation and time-gated single photon counting.

Authors:  Dominic Waithe; Mathias P Clausen; Erdinc Sezgin; Christian Eggeling
Journal:  Bioinformatics       Date:  2015-11-20       Impact factor: 6.937
View more
  4 in total

1.  First-in-clinical application of a time-gated diffuse correlation spectroscopy system at 1064 nm using superconducting nanowire single photon detectors in a neuro intensive care unit.

Authors:  Chien-Sing Poon; Dharminder S Langri; Benjamin Rinehart; Timothy M Rambo; Aaron J Miller; Brandon Foreman; Ulas Sunar
Journal:  Biomed Opt Express       Date:  2022-02-07       Impact factor: 3.732

2.  Time-domain diffuse correlation spectroscopy (TD-DCS) for noninvasive, depth-dependent blood flow quantification in human tissue in vivo.

Authors:  Saeed Samaei; Piotr Sawosz; Michał Kacprzak; Żanna Pastuszak; Dawid Borycki; Adam Liebert
Journal:  Sci Rep       Date:  2021-01-19       Impact factor: 4.379

3.  Development of a Monte Carlo-wave model to simulate time domain diffuse correlation spectroscopy measurements from first principles.

Authors:  Xiaojun Cheng; Hui Chen; Edbert J Sie; Francesco Marsili; David A Boas
Journal:  J Biomed Opt       Date:  2022-02       Impact factor: 3.758

4.  Functional Time Domain Diffuse Correlation Spectroscopy.

Authors:  Nisan Ozana; Niyom Lue; Marco Renna; Mitchell B Robinson; Alyssa Martin; Alexander I Zavriyev; Bryce Carr; Dibbyan Mazumder; Megan H Blackwell; Maria A Franceschini; Stefan A Carp
Journal:  Front Neurosci       Date:  2022-08-01       Impact factor: 5.152
  4 in total

北京卡尤迪生物科技股份有限公司 © 2022-2023.