Feasibility of continuous microvascular tissue oxygenation monitoring using discrete optical semiconductor devices

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dc.contributor.authorPanula, Tuukka
dc.contributor.authorMustajoki, Inka
dc.contributor.authorJaakola, Tomi
dc.contributor.authorNiemi, Tarja
dc.contributor.authorKaisti, Matti
dc.contributor.organizationfi=terveysteknologia|en=Health Technology|
dc.contributor.organizationfi=tyks, vsshp|en=tyks, varha|
dc.contributor.organization-code1.2.246.10.2458963.20.28696315432
dc.converis.publication-id505742630
dc.converis.urlhttps://research.utu.fi/converis/portal/Publication/505742630
dc.date.accessioned2026-01-21T14:32:34Z
dc.date.available2026-01-21T14:32:34Z
dc.description.abstract<p>This study evaluates the potential for the use of low-cost discrete optical semiconductors, specifically light-emitting diodes (LEDs) and a photodiode, for non-invasive measurement of microvascular tissue oxygen saturation (StO). StO is a crucial biomarker in monitoring microvascular function and tissue viability. Spectrometer-based methods typically use complex and expensive equipment, with the cost per patient potentially amounting to hundreds of dollars. This study aims to provide understanding of tissue–light interaction with broader implications extending to applications such as photoplethysmography (PPG). Our approach involves a system that includes three specifically selected LEDs coupled with a photodiode, focusing on assessing microvascular StO. The methodology includes several phases: in vitro calibration using a controlled deoxygenation process in a liquid tissue phantom, computational simulations to estimate the penetration depths of selected LED wavelengths, an analysis of the effects of variability in LED output on measurement accuracy, and a preliminary human study. Results from the in vitro experiments demonstrated a root mean square error of 3.9 StO-% between a spectrometer reference and our technique. The human study including baseline, occlusion and post-occlusion StO measurements in six volunteers resulted in 76.0, 52.6 and 77.5 StO-%, respectively. Computational simulations confirmed the effective penetration of selected wavelengths into targeted microvascular layers. The intrinsic and external factors affecting the measurement accuracy were analyzed. The findings support the feasibility of a cost-effective, simplified, and effective system for continuous monitoring of microvascular tissue oxygenation.<br></p>
dc.identifier.eissn1873-4235
dc.identifier.jour-issn0956-5663
dc.identifier.olddbid213374
dc.identifier.oldhandle10024/196392
dc.identifier.urihttps://www.utupub.fi/handle/11111/55242
dc.identifier.urlhttps://doi.org/10.1016/j.bios.2025.118163
dc.identifier.urnURN:NBN:fi-fe202601216478
dc.language.isoen
dc.okm.affiliatedauthorPanula, Tuukka
dc.okm.affiliatedauthorMustajoki, Inka
dc.okm.affiliatedauthorJaakola, Tomi
dc.okm.affiliatedauthorKaisti, Matti
dc.okm.affiliatedauthorDataimport, tyks, vsshp
dc.okm.discipline113 Computer and information sciencesen_GB
dc.okm.discipline213 Electronic, automation and communications engineering, electronicsen_GB
dc.okm.discipline3126 Surgery, anesthesiology, intensive care, radiologyen_GB
dc.okm.discipline113 Tietojenkäsittely ja informaatiotieteetfi_FI
dc.okm.discipline213 Sähkö-, automaatio- ja tietoliikennetekniikka, elektroniikkafi_FI
dc.okm.discipline3126 Kirurgia, anestesiologia, tehohoito, radiologiafi_FI
dc.okm.internationalcopublicationnot an international co-publication
dc.okm.internationalityInternational publication
dc.okm.typeA1 ScientificArticle
dc.publisherElsevier
dc.publisher.countryUnited Kingdomen_GB
dc.publisher.countryBritanniafi_FI
dc.publisher.country-codeGB
dc.relation.articlenumber118163
dc.relation.doi10.1016/j.bios.2025.118163
dc.relation.ispartofjournalBiosensors and Bioelectronics
dc.relation.volume294
dc.source.identifierhttps://www.utupub.fi/handle/10024/196392
dc.titleFeasibility of continuous microvascular tissue oxygenation monitoring using discrete optical semiconductor devices
dc.year.issued2026

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