Contactless Monitoring of Microcirculation Reaction on Local Temperature Changes

Assessment of skin blood flow is an important clinical task which is required to study mechanisms of microcirculation regulation including thermoregulation. Contactless assessment of vasomotor reactivity in response to thermal exposure is currently not available. The aim of this study is to show the...

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Published inApplied sciences Vol. 9; no. 22; p. 4947
Main Authors Volynsky, Maxim A., Margaryants, Nikita B., Mamontov, Oleg V., Kamshilin, Alexei A.
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.11.2019
Subjects
Blood flow
blood microcirculation
Blood vessels
Capillary flow
Diabetes mellitus
Digital cameras
Dyslipidemia
EKG
Electrocardiography
Exposure
Forehead
Health risks
Heart rate
Heat
Hypertension
imaging photoplethysmography
Laboratories
Medical equipment
Medical imaging
Medical research
Patients
Polarized light
Reactivity
Skin
Skin temperature
Temperature effects
Thermoregulation
Russia
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Summary:Assessment of skin blood flow is an important clinical task which is required to study mechanisms of microcirculation regulation including thermoregulation. Contactless assessment of vasomotor reactivity in response to thermal exposure is currently not available. The aim of this study is to show the applicability of the imaging photoplethysmography (IPPG) method to measure quantitatively the vasomotor response to local thermal exposure. Seventeen healthy subjects aged 23 ± 7 years participated in the study. A warm transparent compress applied to subject’s forehead served as a thermal impact. A custom-made IPPG system operating at green polarized light was used to monitor the subject’s face continuously and simultaneously with skin temperature and electrocardiogram (ECG) recordings. We found that the thermal impact leads to an increase in the amplitude of blood pulsations (BPA) simultaneously with the skin temperature increase. However, a multiple increase in BPA remained after the compress was removed, whereas the skin temperature returned to the baseline. Moreover, the BPA increase and duration of the vasomotor response was associated with the degree of external heating. Therefore, the IPPG method allows us to quantify the parameters of capillary blood flow during local thermal exposure to the skin. This proposed technique of assessing the thermal reactivity of microcirculation can be applied for both clinical use and for biomedical research.
ISSN:2076-3417
2076-3417
DOI:10.3390/app9224947