Two-layered blood-lipid phantom and method to determine absorption and oxygenation employing changes in moments of DTOFs

Sudakou, Aleh; Wabnitz, Heidrun; Liemert, André; Liebert, Adam

doi:10.1364/boe.492168

Cited by 9 publications

(5 citation statements)

References 90 publications

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“…However, absolute values obtained during exercise were generally not comparable between devices unless corrected by physiological calibration after arterial occlusion. This indicates that further efforts should be made to standardize all muscle oximeters, for example, by using tissue-simulating phantoms [ 207 ] and following the guidelines of ISO 80601-2-85:2021 (Medical electrical equipment—Part 2–85: particular requirements for the basic safety and essential performance of cerebral tissue oximeter equipment). The cumbersome instruments, developed for brain oximetry measurements, can be utilized for muscle studies.…”

Section: Discussionmentioning

confidence: 99%

Muscle Oximetry in Sports Science: An Updated Systematic Review

Perrey,

Quaresima,

Ferrari

2024

Sports Med

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Background In the last 5 years since our last systematic review, a significant number of articles have been published on the technical aspects of muscle near-infrared spectroscopy (NIRS), the interpretation of the signals and the benefits of using the NIRS technique to measure the physiological status of muscles and to determine the workload of working muscles. Objectives Considering the consistent number of studies on the application of muscle oximetry in sports science published over the last 5 years, the objectives of this updated systematic review were to highlight the applications of muscle oximetry in the assessment of skeletal muscle oxidative performance in sports activities and to emphasize how this technology has been applied to exercise and training over the last 5 years. In addition, some recent instrumental developments will be briefly summarized. Methods Preferred Reporting Items for Systematic Reviews guidelines were followed in a systematic fashion to search, appraise and synthesize existing literature on this topic. Electronic databases such as Scopus, MEDLINE/PubMed and SPORTDiscus were searched from March 2017 up to March 2023. Potential inclusions were screened against eligibility criteria relating to recreationally trained to elite athletes, with or without training programmes, who must have assessed physiological variables monitored by commercial oximeters or NIRS instrumentation. Results Of the identified records, 191 studies regrouping 3435 participants, met the eligibility criteria. This systematic review highlighted a number of key findings in 37 domains of sport activities. Overall, NIRS information can be used as a meaningful marker of skeletal muscle oxidative capacity and can become one of the primary monitoring tools in practice in conjunction with, or in comparison with, heart rate or mechanical power indices in diverse exercise contexts and across different types of training and interventions. Conclusions Although the feasibility and success of the use of muscle oximetry in sports science is well documented, there is still a need for further instrumental development to overcome current instrumental limitations. Longitudinal studies are urgently needed to strengthen the benefits of using muscle oximetry in sports science.

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Section: Discussionmentioning

confidence: 99%

Muscle Oximetry in Sports Science: An Updated Systematic Review

Perrey,

Quaresima,

Ferrari

2024

Sports Med

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“…Although TiO 2 as a scatterer in the outer matrix and water-soluble nigrosin as an absorber in the vessels proved to be sufficient in the preliminary pulsatility tests required for PPG signal detection, future pulse oximetry experiments could be enhanced by incorporating both static and dynamic absorption values that mimic real tissue. For example, via the addition of a thin epidermal-mimicking layer like those used by Afshari et al [ 13 ] and exploring alternative blood-mimicking fluids, like those used by Sudakou et al [ 21 ].…”

Section: Discussionmentioning

confidence: 99%

“…The necessity of such standardization has been underscored, advocating for the development of optical phantoms as a solution that offers repeatable and controlled testing environments that are both cost-effective and less time-consuming compared to in vivo trials [ 20 ]. Complementing this, several researchers have innovated a two-layered phantoms, which, by incorporating whole human blood into a turbid medium, enables the simulation of dynamic oxygen saturation levels ranging from 0 to 100%, thereby mimicking the complex multi-layered tissue structures found in vivo and enhancing the fidelity of tissue oximetry testing [ 13 , 21 ]. Further emphasizing the importance of anatomical accuracy, researchers have contributed to the field by formulating solid phantoms that not only replicate the 3D shapes of human organs but also possess the properties necessary for thorough calibration and performance analysis of biomedical optics devices, thus paving the way for more precise and anatomically correct biophotonic applications [ 22 , 23 ].…”

Section: Introductionmentioning

confidence: 99%

Tissue mimicking materials and finger phantom design for pulse oximetry

Rodriguez,

Vasudevan,

Farahmand

et al. 2024

Biomed. Opt. Express

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Pulse oximetry represents a ubiquitous clinical application of optics in modern medicine. Recent studies have raised concerns regarding the potential impact of confounders, such as variable skin pigmentation and perfusion, on blood oxygen saturation measurement accuracy in pulse oximeters. Tissue-mimicking phantom testing offers a low-cost, well-controlled solution for characterizing device performance and studying potential error sources, which may thus reduce the need for costly in vivo trials. The purpose of this study was to develop realistic phantom-based test methods for pulse oximetry. Material optical and mechanical properties were reviewed, selected, and tuned for optimal biological relevance, e.g., oxygenated tissue absorption and scattering, strength, elasticity, hardness, and other parameters representing the human finger’s geometry and composition, such as blood vessel size and distribution, and perfusion. Relevant anatomical and physiological properties are summarized and implemented toward the creation of a preliminary finger phantom. To create a preliminary finger phantom, we synthesized a high-compliance silicone matrix with scatterers for embedding flexible tubing and investigated the addition of these scatterers to novel 3D printing resins for optical property control without altering mechanical stability, streamlining the production of phantoms with biologically relevant characteristics. Phantom utility was demonstrated by applying dynamic, pressure waveforms to produce tube volume change and resultant photoplethysmography (PPG) signals. 3D printed phantoms achieved more biologically relevant conditions compared to molded phantoms. These preliminary results indicate that the phantoms show strong potential to be developed into tools for evaluating pulse oximetry performance. Gaps, recommendations, and strategies are presented for continued phantom development.

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“…As the phantom absorption does not influence the dynamic of properties [ 27 ], no absorber was added to the solutions. To set the desired reduced scattering coefficient, various concentrations of the SMOFlipid were added into each mixture following the recipe in [ 28 , 29 ]. Moments of the measured DTOFs were used to calculate the absorption coefficient μ a and the reduced scattering coefficient μ ′ s [ 30 ].…”

Section: Methodsmentioning

confidence: 99%

Time-domain diffuse correlation spectroscopy at large source detector separation for cerebral blood flow recovery

Mogharari,

Wojtkiewicz,

Borycki

et al. 2024

Biomed. Opt. Express

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Time-domain diffuse correlation spectroscopy (td-DCS) enables the depth discrimination in tissue’s blood flow recovery, considering the fraction of photons detected with higher time of flight (TOF) and longer pathlength through the tissue. However, the recovery result depends on factors such as the instrument response function (IRF), analyzed TOF gate start time, gate width and the source-detector separation (SDS). In this research we evaluate the performance of the td-DCS technique at three SDSs of 1.5, 2 and 2.5 cm to recover cerebral blood flow (CBF). To do that we presented comprehensive characterization of the td-DCS system through a series of phantom experiments. First by quality metrices such as coefficient of variation and contrast-to-noise ratios, we identified optimal time gate(s) of the TOF to extract dynamics of particles. Then using sensitivity metrices, each SDS ability to detect dynamics of particles in superficial and deeper layer was evaluated. Finally, td-DCS at each SDS was tested on healthy volunteers during cuff occlusion test and breathing tasks. According to phantom measurements, the sensitivity to estimate perfusion within the deep layer located at depth of 1.5 cm from the surface can be increased more than two times when the SDS increases from 1.5 cm to 2.5 cm.

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Two-layered blood-lipid phantom and method to determine absorption and oxygenation employing changes in moments of DTOFs

Cited by 9 publications

References 90 publications

Muscle Oximetry in Sports Science: An Updated Systematic Review

Muscle Oximetry in Sports Science: An Updated Systematic Review

Tissue mimicking materials and finger phantom design for pulse oximetry

Time-domain diffuse correlation spectroscopy at large source detector separation for cerebral blood flow recovery

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