Compact electron spin resonance skin oximeter: Properties and initial clinical results

Purpose Skin oxygen level is of significance for the diagnosis and treatment of many clinical problems, such as chronic wounds and diabetic foot ulcers. Furthermore, skin oxygen levels can be correlated to arterial oxygen partial pressure, thereby revealing potentially dangerous conditions such as h...

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Published inMagnetic resonance in medicine Vol. 85; no. 5; pp. 2915 - 2925
Main Authors Cristea, David, Wolfson, Helen, Ahmad, Rizwan, Twig, Ygal, Kuppusamy, Periannan, Blank, Aharon
Format Journal Article
LanguageEnglish
Published United States Wiley Subscription Services, Inc 01.05.2021
Subjects
Blood pressure
compact magnet
Diabetes mellitus
Electromagnets
Electron paramagnetic resonance
Electron spin
Electron spin resonance
Fluorescence
Hyperoxia
Matching
Monitoring
Neonates
oximetry
Oxygen
Partial pressure
pulsed ESR
Relaxation time
Sensors
Skin
skin pO2
Spin resonance
Ulcers
pulsed ESR
oximetry
skin pO2
compact magnet
Online AccessGet full text
ISSN0740-3194
1522-2594
1522-2594
DOI10.1002/mrm.28595

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Abstract Purpose Skin oxygen level is of significance for the diagnosis and treatment of many clinical problems, such as chronic wounds and diabetic foot ulcers. Furthermore, skin oxygen levels can be correlated to arterial oxygen partial pressure, thereby revealing potentially dangerous conditions such as hyperoxia (too much oxygen), which may occur in ventilated neonates. Traditionally, skin oxygen levels are measured using electrochemical methods and, more recently, also by fluorescence lifetime techniques. These approaches suffer from several drawbacks, rendering them suboptimal. The purpose of this work is to develop an electron spin resonance (ESR) ‐based method for monitoring oxygen partial pressure (pO2) in skin tissue. Methods A compact sensor for pulsed ESR is designed and constructed. Our ESR‐based method makes use of a unique exogenous paramagnetic spin probe that is placed on the skin in a special partially sealed sticker, and subsequently measuring its signal with the compact pulsed ESR sensor that includes a miniature magnet and a small S‐band (~2.3 GHz) microwave resonator. The inverse of the spin‐spin relaxation time (1/T2) measured by ESR is shown to be linearly correlated with pO2 levels. Results The sensor and its matching sticker were tested both in vitro and in vivo (with human subjects). Measured skin pO2 levels reached equilibrium after ~2‐3 h and were found to be comparable to those measured by continuous‐wave (CW) ESR using a large electromagnet. Conclusions A compact pulsed ESR sensor with a matching paramagnetic sticker can be used for pO2 monitoring of the skin tissue, similar to large bulky CW ESR systems.
AbstractList Skin oxygen level is of significance for the diagnosis and treatment of many clinical problems, such as chronic wounds and diabetic foot ulcers. Furthermore, skin oxygen levels can be correlated to arterial oxygen partial pressure, thereby revealing potentially dangerous conditions such as hyperoxia (too much oxygen), which may occur in ventilated neonates. Traditionally, skin oxygen levels are measured using electrochemical methods and, more recently, also by fluorescence lifetime techniques. These approaches suffer from several drawbacks, rendering them suboptimal. The purpose of this work is to develop an electron spin resonance (ESR) -based method for monitoring oxygen partial pressure (pO ) in skin tissue. A compact sensor for pulsed ESR is designed and constructed. Our ESR-based method makes use of a unique exogenous paramagnetic spin probe that is placed on the skin in a special partially sealed sticker, and subsequently measuring its signal with the compact pulsed ESR sensor that includes a miniature magnet and a small S-band (~2.3 GHz) microwave resonator. The inverse of the spin-spin relaxation time (1/T ) measured by ESR is shown to be linearly correlated with pO levels. The sensor and its matching sticker were tested both in vitro and in vivo (with human subjects). Measured skin pO levels reached equilibrium after ~2-3 h and were found to be comparable to those measured by continuous-wave (CW) ESR using a large electromagnet. A compact pulsed ESR sensor with a matching paramagnetic sticker can be used for pO monitoring of the skin tissue, similar to large bulky CW ESR systems.
PurposeSkin oxygen level is of significance for the diagnosis and treatment of many clinical problems, such as chronic wounds and diabetic foot ulcers. Furthermore, skin oxygen levels can be correlated to arterial oxygen partial pressure, thereby revealing potentially dangerous conditions such as hyperoxia (too much oxygen), which may occur in ventilated neonates. Traditionally, skin oxygen levels are measured using electrochemical methods and, more recently, also by fluorescence lifetime techniques. These approaches suffer from several drawbacks, rendering them suboptimal. The purpose of this work is to develop an electron spin resonance (ESR) ‐based method for monitoring oxygen partial pressure (pO2) in skin tissue.MethodsA compact sensor for pulsed ESR is designed and constructed. Our ESR‐based method makes use of a unique exogenous paramagnetic spin probe that is placed on the skin in a special partially sealed sticker, and subsequently measuring its signal with the compact pulsed ESR sensor that includes a miniature magnet and a small S‐band (~2.3 GHz) microwave resonator. The inverse of the spin‐spin relaxation time (1/T2) measured by ESR is shown to be linearly correlated with pO2 levels.ResultsThe sensor and its matching sticker were tested both in vitro and in vivo (with human subjects). Measured skin pO2 levels reached equilibrium after ~2‐3 h and were found to be comparable to those measured by continuous‐wave (CW) ESR using a large electromagnet.ConclusionsA compact pulsed ESR sensor with a matching paramagnetic sticker can be used for pO2 monitoring of the skin tissue, similar to large bulky CW ESR systems.
Purpose Skin oxygen level is of significance for the diagnosis and treatment of many clinical problems, such as chronic wounds and diabetic foot ulcers. Furthermore, skin oxygen levels can be correlated to arterial oxygen partial pressure, thereby revealing potentially dangerous conditions such as hyperoxia (too much oxygen), which may occur in ventilated neonates. Traditionally, skin oxygen levels are measured using electrochemical methods and, more recently, also by fluorescence lifetime techniques. These approaches suffer from several drawbacks, rendering them suboptimal. The purpose of this work is to develop an electron spin resonance (ESR) ‐based method for monitoring oxygen partial pressure (pO2) in skin tissue. Methods A compact sensor for pulsed ESR is designed and constructed. Our ESR‐based method makes use of a unique exogenous paramagnetic spin probe that is placed on the skin in a special partially sealed sticker, and subsequently measuring its signal with the compact pulsed ESR sensor that includes a miniature magnet and a small S‐band (~2.3 GHz) microwave resonator. The inverse of the spin‐spin relaxation time (1/T2) measured by ESR is shown to be linearly correlated with pO2 levels. Results The sensor and its matching sticker were tested both in vitro and in vivo (with human subjects). Measured skin pO2 levels reached equilibrium after ~2‐3 h and were found to be comparable to those measured by continuous‐wave (CW) ESR using a large electromagnet. Conclusions A compact pulsed ESR sensor with a matching paramagnetic sticker can be used for pO2 monitoring of the skin tissue, similar to large bulky CW ESR systems.
Skin oxygen level is of significance for the diagnosis and treatment of many clinical problems, such as chronic wounds and diabetic foot ulcers. Furthermore, skin oxygen levels can be correlated to arterial oxygen partial pressure, thereby revealing potentially dangerous conditions such as hyperoxia (too much oxygen), which may occur in ventilated neonates. Traditionally, skin oxygen levels are measured using electrochemical methods and, more recently, also by fluorescence lifetime techniques. These approaches suffer from several drawbacks, rendering them suboptimal. The purpose of this work is to develop an electron spin resonance (ESR) -based method for monitoring oxygen partial pressure (pO2 ) in skin tissue.PURPOSESkin oxygen level is of significance for the diagnosis and treatment of many clinical problems, such as chronic wounds and diabetic foot ulcers. Furthermore, skin oxygen levels can be correlated to arterial oxygen partial pressure, thereby revealing potentially dangerous conditions such as hyperoxia (too much oxygen), which may occur in ventilated neonates. Traditionally, skin oxygen levels are measured using electrochemical methods and, more recently, also by fluorescence lifetime techniques. These approaches suffer from several drawbacks, rendering them suboptimal. The purpose of this work is to develop an electron spin resonance (ESR) -based method for monitoring oxygen partial pressure (pO2 ) in skin tissue.A compact sensor for pulsed ESR is designed and constructed. Our ESR-based method makes use of a unique exogenous paramagnetic spin probe that is placed on the skin in a special partially sealed sticker, and subsequently measuring its signal with the compact pulsed ESR sensor that includes a miniature magnet and a small S-band (~2.3 GHz) microwave resonator. The inverse of the spin-spin relaxation time (1/T2 ) measured by ESR is shown to be linearly correlated with pO2 levels.METHODSA compact sensor for pulsed ESR is designed and constructed. Our ESR-based method makes use of a unique exogenous paramagnetic spin probe that is placed on the skin in a special partially sealed sticker, and subsequently measuring its signal with the compact pulsed ESR sensor that includes a miniature magnet and a small S-band (~2.3 GHz) microwave resonator. The inverse of the spin-spin relaxation time (1/T2 ) measured by ESR is shown to be linearly correlated with pO2 levels.The sensor and its matching sticker were tested both in vitro and in vivo (with human subjects). Measured skin pO2 levels reached equilibrium after ~2-3 h and were found to be comparable to those measured by continuous-wave (CW) ESR using a large electromagnet.RESULTSThe sensor and its matching sticker were tested both in vitro and in vivo (with human subjects). Measured skin pO2 levels reached equilibrium after ~2-3 h and were found to be comparable to those measured by continuous-wave (CW) ESR using a large electromagnet.A compact pulsed ESR sensor with a matching paramagnetic sticker can be used for pO2 monitoring of the skin tissue, similar to large bulky CW ESR systems.CONCLUSIONSA compact pulsed ESR sensor with a matching paramagnetic sticker can be used for pO2 monitoring of the skin tissue, similar to large bulky CW ESR systems.
Author Blank, Aharon
Cristea, David
Wolfson, Helen
Ahmad, Rizwan
Twig, Ygal
Kuppusamy, Periannan
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  organization: Technion–Israel Institute of Technology
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Keywords pulsed ESR
oximetry
skin pO2
compact magnet
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Snippet Purpose Skin oxygen level is of significance for the diagnosis and treatment of many clinical problems, such as chronic wounds and diabetic foot ulcers....
Skin oxygen level is of significance for the diagnosis and treatment of many clinical problems, such as chronic wounds and diabetic foot ulcers. Furthermore,...
PurposeSkin oxygen level is of significance for the diagnosis and treatment of many clinical problems, such as chronic wounds and diabetic foot ulcers....
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SubjectTerms Blood pressure
compact magnet
Diabetes mellitus
Electromagnets
Electron paramagnetic resonance
Electron spin
Electron spin resonance
Fluorescence
Hyperoxia
Matching
Monitoring
Neonates
oximetry
Oxygen
Partial pressure
pulsed ESR
Relaxation time
Sensors
Skin
skin pO2
Spin resonance
Ulcers
Title Compact electron spin resonance skin oximeter: Properties and initial clinical results
URI https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fmrm.28595
https://www.ncbi.nlm.nih.gov/pubmed/33210362
https://www.proquest.com/docview/2484155370
https://www.proquest.com/docview/2462414985
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