Oxygen sensing performance of biodegradable electrospun nanofibers: Influence of fiber composition and core-shell geometry

[Display omitted] •Assessed porphyrin-containing biodegradable electrospun dissolved oxygen (DO) sensors.•Red excitation and near-infrared emission ideal for in vivo applications.•In situ setup for phosphorescent lifetime collection and real-time DO verification.•Sensors exhibit linear Stern-Volmer...

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Published in:Sensors and actuators. B, Chemical Chemical, 2021-02, Vol.329, p.129191, Article 129191
Main Authors: Presley, Kayla F., Reinsch, Bonnie M., Cybyk, Daniel B., Ly, Jack T., Schweller, Ryan M., Dalton, Matthew J., Lannutti, John J., Grusenmeyer, Tod A.
Format: Article
Language:English
Subjects:
Biocompatibility
Biodegradability
Biodegradable polymer
Biomedical materials
Chromophores
Composition
Decay
Electrospinning
Fluorometers
Gelatin
Nanofibers
Optical sensor
Oxygen probes
Oxygen sensing
Oxygenation
Phosphorescence
Phosphorescence lifetime
Polycaprolactone
Polymers
Porphyrin
Sensitivity
Sensors
Surgical implants
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Summary:[Display omitted] •Assessed porphyrin-containing biodegradable electrospun dissolved oxygen (DO) sensors.•Red excitation and near-infrared emission ideal for in vivo applications.•In situ setup for phosphorescent lifetime collection and real-time DO verification.•Sensors exhibit linear Stern-Volmer plots for ease of calibration and interpretation.•Performance of core-shell and blended PCL:gelatin fibers similar to pure PCL sensor. The ability to continuously monitor tissue oxygenation in vivo is highly desired for a variety of biomedical applications. Implantable optical oxygen sensors can be constructed through incorporation of an oxygen-sensitive chromophore within a biocompatible polymer host. In this work, a Pd (II) benzoporphyrin that absorbs (630 nm) and phosphoresces (810 nm) within the optical tissue window was incorporated into various biodegradable polymer matrices via electrospinning. A unique in situ fluorimeter setup was constructed and used to rigorously characterize the sensor performance in the physiologically relevant dissolved oxygen range (∼0−90 μM) in 37 °C phosphate buffered saline. Single-component polycaprolactone (PCL) fibers exhibited high sensitivity (KSV: 1.25 × 105 M−1) and monoexponential decay curves, indicating a homogenous chromophore environment. The ability to move from a single-component composition (PCL) to blended (PCL:gelatin) and core-shell systems (PCL:gelatin-PCL) without compromising the desirable properties of the single-component sensor was demonstrated. These variations may offer the potential to tune degradation time of the resulting sensor while maintaining high sensitivity and monoexponential decays. In contrast, blended 50:50 PCL:poly(d,l-lactide-co-glycolide) (PLGA) exhibited significantly reduced sensitivity (KSV: 6.66 × 104 M−1) and biexponential decays. Despite the observation of biexponential lifetime decays for PCL:PLGA, all electrospun sensors exhibited linear Stern-Volmer behavior over the physiologically relevant dissolved oxygen range. This work rigorously evaluated biodegradable candidates for in vivo oxygen sensing under physiologically relevant conditions in which the character of the individual phosphorescence decay curves offered insight into the nature of the chromophore environment.
ISSN:0925-4005
1873-3077
DOI:10.1016/j.snb.2020.129191