Your search keyword '"Maria A. Franceschini"' showing total 10 results

1. Diffuse correlation spectroscopy: current status and future outlook

Author

Stefan A. Carp, Mitchell B. Robinson, and Maria A. Franceschini

Subjects

Radiological and Ultrasound Technology, Neuroscience (miscellaneous), Radiology, Nuclear Medicine and imaging

Published

2023

2. Erratum: Improved accuracy of cerebral blood flow quantification in the presence of systemic physiology cross-talk using multi-layer Monte Carlo modeling

Author

Melissa M. Wu, Suk-Tak Chan, Dibbyan Mazumder, Davide Tamborini, Kimberly A. Stephens, Bin Deng, Parya Farzam, Joyce Y. Chu, Maria A. Franceschini, Jason Z. Qu, and Stefan A. Carp

Subjects

Radiological and Ultrasound Technology, Neuroscience (miscellaneous), Radiology, Nuclear Medicine and imaging

Published

2022

3. Superconducting nanowire single-photon sensing of cerebral blood flow

Author

Maria Angela Franceschini, Dibbyan Mazumder, Alexander I. Zavriyev, Mitchell B. Robinson, Nisan Ozana, Stefan A. Carp, Megan H. Blackwell, and Kutlu Kaya

Subjects

Paper, diffuse correlation spectroscopy, Avalanche diode, Materials science, Radiological and Ultrasound Technology, cerebral blood flow, Neuroscience (miscellaneous), Pulsatile flow, Blood flow, Research Papers, pulsatile blood flow, Cerebral blood flow, Signal-to-noise ratio (imaging), Intensive care, Radiology, Nuclear Medicine and imaging, Cerebral perfusion pressure, superconducting nanowire detectors, Sensitivity (electronics), Biomedical engineering

Abstract

Significance: The ability of diffuse correlation spectroscopy (DCS) to measure cerebral blood flow (CBF) in humans is hindered by the low signal-to-noise ratio (SNR) of the method. This limits the high acquisition rates needed to resolve dynamic flow changes and to optimally filter out large pulsatile oscillations and prevents the use of large source-detector separations (≥3 cm), which are needed to achieve adequate brain sensitivity in most adult subjects. Aim: To substantially improve SNR, we have built a DCS device that operates at 1064 nm and uses superconducting nanowire single-photon detectors (SNSPD). Approach: We compared the performances of the SNSPD-DCS in humans with respect to a typical DCS system operating at 850 nm and using silicon single-photon avalanche diode detectors. Results: At a 25-mm separation, we detected 13 ± 6 times more photons and achieved an SNR gain of 16 ± 8 on the forehead of 11 subjects using the SNSPD-DCS as compared to typical DCS. At this separation, the SNSPD-DCS is able to detect a clean pulsatile flow signal at 20 Hz in all subjects. With the SNSPD-DCS, we also performed measurements at 35 mm, showing a lower scalp sensitivity of 31 ± 6 % with respect to the 48 ± 8 % scalp sensitivity at 25 mm for both the 850 and 1064 nm systems. Furthermore, we demonstrated blood flow responses to breath holding and hyperventilation tasks. Conclusions: While current commercial SNSPDs are expensive, bulky, and loud, they may allow for more robust measures of non-invasive cerebral perfusion in an intensive care setting.

Published

2021

4. Optimization of time domain diffuse correlation spectroscopy parameters for measuring brain blood flow

Author

Melissa M. Wu, Nisan Ozana, Davide Tamborini, Maria Angela Franceschini, Dibbyan Mazumder, and Stefan A. Carp

Subjects

Time delay and integration, Physics, Paper, instrument response function, Radiological and Ultrasound Technology, Acoustics, Monte Carlo method, Neuroscience (miscellaneous), time domain diffuse correlation spectroscopy, Pulse duration, Noise (electronics), Research Papers, Imaging phantom, Simulation noise, cerebral blood flow measurement, Radiology, Nuclear Medicine and imaging, Time domain, Sensitivity (control systems), optimization, Monte Carlo simulation

Abstract

Significance: Time domain diffuse correlation spectroscopy (TD-DCS) can offer increased sensitivity to cerebral hemodynamics and reduced contamination from extracerebral layers by differentiating photons based on their travel time in tissue. We have developed rigorous simulation and evaluation procedures to determine the optimal time gate parameters for monitoring cerebral perfusion considering instrumentation characteristics and realistic measurement noise. Aim: We simulate TD-DCS cerebral perfusion monitoring performance for different instrument response functions (IRFs) in the presence of realistic experimental noise and evaluate metrics of sensitivity to brain blood flow, signal-to-noise ratio (SNR), and ability to reject the influence of extracerebral blood flow across a variety of time gates to determine optimal operating parameters. Approach: Light propagation was modeled on an MRI-derived human head geometry using Monte Carlo simulations for 765- and 1064-nm excitation wavelengths. We use a virtual probe with a source–detector separation of 1 cm placed in the pre-frontal region. Performance metrics described above were evaluated to determine optimal time gate(s) for different IRFs. Validation of simulation noise estimates was done with experiments conducted on an intralipid-based liquid phantom. Results: We find that TD-DCS performance strongly depends on the system IRF. Among Gaussian pulse shapes, ∼300 ps pulse length appears to offer the best performance, at wide gates (500 ps and larger) with start times 400 and 600 ps after the peak of the TPSF at 765 and 1064 nm, respectively, for a 1-s integration time at photon detection rates seen experimentally (600 kcps at 765 nm and 4 Mcps at 1064 nm). Conclusions: Our work shows that optimal time gates satisfy competing requirements for sufficient sensitivity and sufficient SNR. The achievable performance is further impacted by system IRF with ∼300 ps quasi-Gaussian pulse obtained using electro-optic laser shaping providing the best results.

Published

2021

5. Errata: Best practices for fNIRS publications

Author

Heidrun Wabnitz, Christophe Grova, Alessandro Torricelli, Joseph P. Culver, Meryem A. Yücel, Judit Gervain, Robert J. Cooper, Fumitaka Homae, Hellmuth Obrig, Yunjie Tong, Ilias Tachtsidis, Ippeita Dan, Felix Scholkmann, Martin Wolf, Maria Angela Franceschini, Clare E. Elwell, Adam T. Eggebrecht, Alexander von Lühmann, Frédéric Lesage, David A. Boas, Hasan Ayaz, and Sungho Tak

Subjects

medicine.medical_specialty, Radiological and Ultrasound Technology, Computer science, Best practice, Published Erratum, Neuroscience (miscellaneous), MEDLINE, medicine, Radiology, Nuclear Medicine and imaging, Medical physics, Medical research

Published

2021

6. Improved accuracy of cerebral blood flow quantification in the presence of systemic physiology cross-talk using multi-layer Monte Carlo modeling

Author

Maria Angela Franceschini, Stefan A. Carp, Melissa M. Wu, Suk-Tak Chan, Davide Tamborini, Dibbyan Mazumder, Kimberly A. Stephens, Bin Deng, Joyce Yawei Chu, Parya Farzam, and Jason Z. Qu

Subjects

Paper, Materials science, Flow (psychology), Monte Carlo method, cerebral blood flow, Neuroscience (miscellaneous), Physiology, Translation (geometry), 01 natural sciences, 010309 optics, 03 medical and health sciences, 0302 clinical medicine, 0103 physical sciences, Modulation (music), Radiology, Nuclear Medicine and imaging, Multi layer, Monte Carlo, diffuse correlation spectroscopy, Radiological and Ultrasound Technology, hypercapnia, Diffuse correlation spectroscopy, Blood flow, Research Papers, multi-layer, Cerebral blood flow, 030217 neurology & neurosurgery

Abstract

Significance: Contamination of diffuse correlation spectroscopy (DCS) measurements of cerebral blood flow (CBF) due to systemic physiology remains a significant challenge in the clinical translation of DCS for neuromonitoring. Tunable, multi-layer Monte Carlo-based (MC) light transport models have the potential to remove extracerebral flow cross-talk in cerebral blood flow index (CBFi) estimates. Aim: We explore the effectiveness of MC DCS models in recovering accurate CBFi changes in the presence of strong systemic physiology variations during a hypercapnia maneuver. Approach: Multi-layer slab and head-like realistic (curved) geometries were used to run MC simulations of photon propagation through the head. The simulation data were post-processed into models with variable extracerebral thicknesses and used to fit DCS multi-distance intensity autocorrelation measurements to estimate CBFi timecourses. The results of the MC CBFi values from a set of human subject hypercapnia sessions were compared with CBFi values estimated using a semi-infinite analytical model, as commonly used in the field. Results: Group averages indicate a gradual systemic increase in blood flow following a different temporal profile versus the expected rapid CBF response. Optimized MC models, guided by several intrinsic criteria and a pressure modulation maneuver, were able to more effectively separate CBFi changes from scalp blood flow influence than the analytical fitting, which assumed a homogeneous medium. Three-layer models performed better than two-layer ones; slab and curved models achieved largely similar results, though curved geometries were closer to physiological layer thicknesses. Conclusion: Three-layer, adjustable MC models can be useful in separating distinct changes in scalp and brain blood flow. Pressure modulation, along with reasonable estimates of physiological parameters, can help direct the choice of appropriate layer thicknesses in MC models.

Published

2021

7. Prolonged monitoring of cerebral blood flow and autoregulation with diffuse correlation spectroscopy in neurocritical care patients

Author

Juliette, Selb, Kuan-Cheng, Wu, Jason, Sutin, Pei-Yi Ivy, Lin, Parisa, Farzam, Sophia, Bechek, Apeksha, Shenoy, Aman B, Patel, David A, Boas, Maria Angela, Franceschini, and Eric S, Rosenthal

Subjects

010309 optics, 03 medical and health sciences, 0302 clinical medicine, Radiological and Ultrasound Technology, Errata, 0103 physical sciences, Neuroscience (miscellaneous), Radiology, Nuclear Medicine and imaging, 01 natural sciences, 030217 neurology & neurosurgery

Abstract

Monitoring of cerebral blood flow (CBF) and autoregulation are essential components of neurocritical care, but continuous noninvasive methods for CBF monitoring are lacking. Diffuse correlation spectroscopy (DCS) is a noninvasive diffuse optical modality that measures a CBF index (

Published

2017

8. Erratum: Prolonged monitoring of cerebral blood flow and autoregulation with diffuse correlation spectroscopy in neurocritical care patients

Author

Jason Sutin, Apeksha Shenoy, Sophia Bechek, Parisa Farzam, Aman B. Patel, Kuan-Cheng Wu, Eric Rosenthal, Pei-Yi Ivy Lin, Juliette Selb, David A. Boas, and Maria Angela Franceschini

Subjects

medicine.medical_specialty, Subarachnoid hemorrhage, Neurology, Radiological and Ultrasound Technology, business.industry, Neuroscience (miscellaneous), Neurointensive care, medicine.disease, Research Papers, Cerebral autoregulation, Blood pressure, Cerebral blood flow, Internal medicine, medicine, Cardiology, Radiology, Nuclear Medicine and imaging, Autoregulation, Cerebral perfusion pressure, business

Abstract

Monitoring of cerebral blood flow (CBF) and autoregulation are essential components of neurocritical care, but continuous noninvasive methods for CBF monitoring are lacking. Diffuse correlation spectroscopy (DCS) is a noninvasive diffuse optical modality that measures a CBF index ([Formula: see text]) in the cortex microvasculature by monitoring the rapid fluctuations of near-infrared light diffusing through moving red blood cells. We tested the feasibility of monitoring [Formula: see text] with DCS in at-risk patients in the Neurosciences Intensive Care Unit. DCS data were acquired continuously for up to 20 h in six patients with aneurysmal subarachnoid hemorrhage, as permitted by clinical care. Mean arterial blood pressure was recorded synchronously, allowing us to derive autoregulation curves and to compute an autoregulation index. The autoregulation curves suggest disrupted cerebral autoregulation in most patients, with the severity of disruption and the limits of preserved autoregulation varying between subjects. Our findings suggest the potential of the DCS modality for noninvasive, long-term monitoring of cerebral perfusion, and autoregulation.

Published

2020

9. Development and characterization of a multidistance and multiwavelength diffuse correlation spectroscopy system

Author

Kuan-Cheng Wu, Bernhard B. Zimmermann, Parisa Farzam, Maria Angela Franceschini, Davide Tamborini, and David A. Boas

Subjects

Physics, Optical fiber, Radiological and Ultrasound Technology, business.industry, Scattering, Physics::Medical Physics, Near-infrared spectroscopy, Neuroscience (miscellaneous), Laser, 01 natural sciences, Imaging phantom, Special Section on Functional Near Infrared Spectroscopy, Part 3, law.invention, Coherence length, 010309 optics, 03 medical and health sciences, Light intensity, 0302 clinical medicine, Optics, law, 0103 physical sciences, Optical correlator, Radiology, Nuclear Medicine and imaging, business, 030217 neurology & neurosurgery

Abstract

This paper presents a multidistance and multiwavelength diffuse correlation spectroscopy (DCS) approach and its implementation to simultaneously measure the optical proprieties of deep tissue as well as the blood flow. The system consists of three long coherence length lasers at different wavelengths in the near-infrared, eight single-photon detectors, and a correlator board. With this approach, we collect both light intensity and DCS data at multiple distances and multiple wavelengths, which provide unique information to fit for all the parameters of interest: scattering, blood flow, and hemoglobin concentration. We present the characterization of the system and its validation with phantom measurements.

Published

2017

10. Diffuse correlation spectroscopy for measurement of cerebral blood flow: future prospects

Author

P. Ellen Grant, Ashwin B. Parthasarathy, Arjun G. Yodh, Maria Angela Franceschini, and Erin M. Buckley

Subjects

Brain development, Radiological and Ultrasound Technology, business.industry, Special Section Papers, Neuroscience (miscellaneous), Diffuse correlation spectroscopy, Blood flow, 01 natural sciences, Patient management, 010309 optics, 03 medical and health sciences, 0302 clinical medicine, Tissue optics, Cerebral blood flow, Blood circulation, 0103 physical sciences, Medicine, Radiology, Nuclear Medicine and imaging, Neurovascular coupling, business, Neuroscience, 030217 neurology & neurosurgery

Abstract

Diffuse correlation spectroscopy (DCS) is an emerging optical modality used to measure cortical cerebral blood flow. This outlook presents a brief overview of the technology, summarizing the advantages and limitations of the method, and describing its recent applications to animal, adult, and infant cohorts. At last, the paper highlights future applications where DCS may play a pivotal role individualizing patient management and enhancing our understanding of neurovascular coupling, activation, and brain development.

Published

2014