A scalable correlator for multichannel diffuse correlation spectroscopy

Stapels, Christopher J.; Kolodziejski, Noah J.; McAdams, Daniel R.; Podolsky, Matthew J.; Fernandez, Daniel E.; Farkas, Dana; Christian, James F.

doi:10.1117/12.2213114

Cited by 9 publications

(8 citation statements)

References 6 publications

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“…This relationship between flow speed and a characteristic of the autocorrelation is all that is needed for DCS at its most basic level 3,5 . The phantom exhibits the pattern that it needs to replicate in order to be useful for baselining in vivo DCS experiments and instrument testing.…”

Section: Resultsmentioning

confidence: 99%

“…A solid phantom remains inert and unaltered between experiments, allowing for effective benchmarking of instruments against a standard. A variety of solid and gel phantoms have been developed, although they generally only have a singular, large tube carrying liquid through the phantom 5,6 . This is not an accurate model of human tissue, where the majority of movement is blood flowing through capillaries.…”

Section: Introductionmentioning

confidence: 99%

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A capillary-mimicking optical tissue phantom for diffuse correlation spectroscopy

et al. 2017

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Optical tissue phantoms are necessary for instrument benchmarking and providing a consistent baseline for experiments in various fields of tissue spectroscopy, including diffuse correlation spectroscopy (DCS). To provide the most useful comparisons, a phantom would ideally mimic tissue as closely as possible, including the geometry of static and dynamic scatterers. A branching design that keeps the capillary cross section constant ensures that the same flow velocity is found throughout the phantom while allowing for single input and output fittings to feed all of the capillaries simultaneously. The direction of each capillary is randomized every few millimeters by randomly allocating 2 by 2 “twisting” squares within each layer. These squares swap the locations of four adjacent artificial capillaries either clockwise or counterclockwise. Numerical simulations were used to verify the random walk-like behavior of the capillary paths resulting from this pattern. This is a step toward replicating the randomly varying directionality of actual capillaries. This design was verified by taking DCS measurements at different flow rates of Intralipid through the phantom, demonstrating the effect of the flow rate on the characteristic decay time of the autocorrelation.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A capillary-mimicking optical tissue phantom for diffuse correlation spectroscopy

et al. 2017

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“…For cost-effective construction of the device, DCS employs an inexpensive laser diode (LD) with a long coherence length to cover a sample volume. Instead of the commercialized hardware correlator, the correlator is implemented using a custom PSoc time-tagger and USB logger [10]. DRS uses a white LED as a broadband source and a miniaturized spectrometer (Avantes) to acquire a reflectance spectrum (450 ~ 650 nm).…”

Section: Methodsmentioning

confidence: 99%

“…A block diagram of the PSOC operating code is shown in Figure 3. Further details on the construction, design and operation of the DCS instrument is provided in [10]. …”

Section: Methodsmentioning

confidence: 99%

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Novel diffuse optics system for continuous tissue viability monitoring: extended recovery in vivo testing in a porcine flap model

et al. 2017

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In reconstructive surgery, tissue perfusion/vessel patency is critical to the success of microvascular free tissue flaps. Early detection of flap failure secondary to compromise of vascular perfusion would significantly increase the chances of flap salvage. We have developed a compact, clinically-compatible monitoring system to enable automated, minimally-invasive, continuous, and quantitative assessment of flap viability/perfusion. We tested the system’s continuous monitoring capability during extended non-recovery surgery using an in vivo porcine free flap model. Initial results indicated that the system could assess flap viability/perfusion in a quantitative and continuous manner. With proven performance, the compact form constructed with cost-effective components would make this system suitable for clinical translation

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Fast and sensitive diffuse correlation spectroscopy with highly parallelized single photon detection

Liu

Qian

et al. 2021

APL Photonics

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Diffuse correlation spectroscopy (DCS) is a well-established method that measures rapid changes in scattered coherent light to identify blood flow and functional dynamics within a tissue. While its sensitivity to minute scatterer displacements leads to a number of unique advantages, conventional DCS systems become photon-limited when attempting to probe deep into the tissue, which leads to long measurement windows (∽1 sec). Here, we present a high-sensitivity DCS system with 1024 parallel detection channels integrated within a single-photon avalanche diode array and demonstrate the ability to detect mm-scale perturbations up to 1 cm deep within a tissue-like phantom at up to a 33 Hz sampling rate. We also show that this highly parallelized strategy can measure the human pulse at high fidelity and detect behaviorally induced physiological variations from above the human prefrontal cortex. By greatly improving the detection sensitivity and speed, highly parallelized DCS opens up new experiments for high-speed biological signal measurement.

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A scalable correlator for multichannel diffuse correlation spectroscopy

Cited by 9 publications

References 6 publications

A capillary-mimicking optical tissue phantom for diffuse correlation spectroscopy

A capillary-mimicking optical tissue phantom for diffuse correlation spectroscopy

Novel diffuse optics system for continuous tissue viability monitoring: extended recovery in vivo testing in a porcine flap model

Fast and sensitive diffuse correlation spectroscopy with highly parallelized single photon detection

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