Fiber-optic fluorescence-quenching oxygen partial pressure sensor using platinum octaethylporphyrin

John J. Davenport; Michelle Hickey; Justin P. Phillips; Panayiotis A. Kyriacou

doi:10.1364/AO.55.005603

Applied Optics
Vol. 55,
Issue 21,
pp. 5603-5609
(2016)
•https://doi.org/10.1364/AO.55.005603

Fiber-optic fluorescence-quenching oxygen partial pressure sensor using platinum octaethylporphyrin

John J. Davenport, Michelle Hickey, Justin P. Phillips, and Panayiotis A. Kyriacou

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John J. Davenport, Michelle Hickey, Justin P. Phillips, and Panayiotis A. Kyriacou, "Fiber-optic fluorescence-quenching oxygen partial pressure sensor using platinum octaethylporphyrin," Appl. Opt. 55, 5603-5609 (2016)

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Table of Contents Category
- Fiber Optics and Optical Communications
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About this Article
History
- Original Manuscript: April 4, 2016
- Revised Manuscript: May 23, 2016
- Manuscript Accepted: June 20, 2016
- Published: July 14, 2016
Virtual Issues
Virtual Journal for Biomedical Optics Vol. 11, Iss. 8

Abstract

The development and bench testing of a fiber-optic oxygen sensor is described. The sensor is designed for measurement of tissue oxygen levels in the mucosa of the digestive tract. The materials and construction are optimized for insertion through the mouth for measurement in the lower esophagus. An oxygen-sensitive fluorescence-quenching film was applied as a solution of platinum octaethylporphyrin (PtOEP) poly(ethyl methacrylate) (PEMA) and dichloromethane and dip coated onto the distal tip of the fiber. The sensor was tested by comparing relative fluorescence when immersed in liquid water at 37°C, at a range of partial pressures (0–101 kPa). Maximum relative fluorescence at most oxygen concentrations was seen when the PtOEP concentration was $0.1 {g.L}^{- 1}$ , four layers of coating solution were applied, and a fiber core radius of 600 μm was selected, giving a Stern–Volmer constant of $0.129 {kPa}^{- 1}$ . The performance of the sensor is suitable for many in vivo applications, particularly mucosal measurements. It has sufficient sensitivity, is sterilizable, and is sufficiently flexible and robust for insertion via the mouth without damage to the probe or risk of harm to the patient.

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Fiber	Core Diameter (μm)	Core Material	Numerical Aperture	Bend Radius (Momentary) (mm)
BFL48-400	400	Silica	0.48	40
BFL48-600	600	Silica	0.48	60
BFL48-1000	1000	Silica	0.48	100

$O_{2}$ Flow Rate ( $mL \cdot \min^{- 1}$ )	$N_{2}$ Flow Rate ( $mL \cdot \min^{- 1}$ )	$O_{2}$ Percentage (%)	$O_{2}$ Partial Pressure (kPa)
0	1000	$0 \pm 3$	$0 \pm 3$
200	800	$20 \pm 3$	$20 \pm 3$
400	600	$40 \pm 3$	$41 \pm 3$
600	400	$60 \pm 3$	$61 \pm 3$
800	200	$80 \pm 3$	$81 \pm 3$
900	100	$90 \pm 3$	$91 \pm 3$
1000	0	$100 \pm 3$	$101 \pm 3$

Batch	PtOEP (mg)	PEMA (mg)	${CH}_{2} {Cl}_{2}$ (mL)	PtOEP Concentration ( $g \cdot L^{- 1}$ )
a	0.2	100	2.0	0.1
b	0.4	100	2.0	0.2
c	1.0	100	2.0	0.5
d	1.5	100	2.0	0.75

Parameter	Selected Value
Fluorophore concentration	0.1 g/l
Number of coating layers	Four
Fiber core diameter	600 μm

Fiber	Core Diameter (μm)	Core Material	Numerical Aperture	Bend Radius (Momentary) (mm)
BFL48-400	400	Silica	0.48	40
BFL48-600	600	Silica	0.48	60
BFL48-1000	1000	Silica	0.48	100

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