Comparison of Fabrication Methods for Fiber-Optic Ultrasound Transmitters Using Candle-Soot Nanoparticles

Semyon Bodian; Esra Aytac‐Kipergil; Shaoyan Zhang; India Lewis‐Thompson; Sanjayan Sathasivam; Sunish J. Mathews; Erwin J. Alles; Edward Z. Zhang; Paul C. Beard; Ross J. Gordon; Paul Collier; Ivan P. Parkin; Adrien E. Desjardins; Richard J. Colchester; Sacha Noimark

doi:10.1002/admi.202201792

Comparison of Fabrication Methods for Fiber-Optic Ultrasound Transmitters Using Candle-Soot Nanoparticles

Semyon Bodian (Lead / Corresponding author), Esra Aytac‐Kipergil, Shaoyan Zhang, India Lewis‐Thompson, Sanjayan Sathasivam, Sunish J. Mathews, Erwin J. Alles, Edward Z. Zhang, Paul C. Beard, Ross J. Gordon, Paul Collier, Ivan P. Parkin, Adrien E. Desjardins, Richard J. Colchester, Sacha Noimark

Biomedical Engineering

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Abstract

Candle-soot nanoparticles (CSNPs) have shown great promise for fabricating optical ultrasound (OpUS) transmitters. They have a facile, inexpensive synthesis whilst their unique, porous structure enables a fast heat diffusion rate which aids high-frequency ultrasound generation necessary for high-resolution clinical imaging. These composites have demonstrated high ultrasound
generation performance showing clinically relevant detail, when applied as macroscale OpUS transmitters comprising both concave and planar surfaces, however, less research has been invested into the translation of this material’s technology to fabricate fiber-optic transmitters for image guidance of
minimally invasive interventions. Here, are reported two fabrication methods of nanocomposites composed of CSNPs embedded within polydimethylsiloxane (PDMS) deposited onto fiber-optic end-faces using two different optimized fabrication methods: “All-in-One” and “Direct Deposition.” Both types
of nanocomposite exhibit a smooth, black domed structure with a maximum dome thickness of 50 µm, broadband optical absorption (>98% between 500 and 1400 nm) and both nanocomposites generated high peak-to-peak ultrasound pressures (>3 MPa) and wide bandwidths (>29 MHz). Further,
high-resolution (<40 µm axial resolution) B-mode ultrasound imaging of exvivo lamb brain tissue demonstrating how CSNP-PDMS OpUS transmitters can allow for high fidelity minimally invasive imaging of biological tissues is demonstrated.

Original language	English
Article number	2201792
Number of pages	11
Journal	Advanced Materials Interfaces
Volume	10
Issue number	9
Early online date	24 Feb 2023
DOIs	https://doi.org/10.1002/admi.202201792
Publication status	Published - 24 Mar 2023

Keywords

brain imaging
candle soot nanoparticles
optical fibers
optical ultrasound
polydimethylsiloxane

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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Final published versionFinal published version, 2 MBLicence: CC BY

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Bodian, S., Aytac‐Kipergil, E., Zhang, S., Lewis‐Thompson, I., Sathasivam, S., Mathews, S. J., Alles, E. J., Zhang, E. Z., Beard, P. C., Gordon, R. J., Collier, P., Parkin, I. P., Desjardins, A. E., Colchester, R. J., & Noimark, S. (2023). Comparison of Fabrication Methods for Fiber-Optic Ultrasound Transmitters Using Candle-Soot Nanoparticles. Advanced Materials Interfaces, 10(9), Article 2201792. https://doi.org/10.1002/admi.202201792

@article{b1c464463d95433fa6631d3062bda381,

title = "Comparison of Fabrication Methods for Fiber-Optic Ultrasound Transmitters Using Candle-Soot Nanoparticles",

abstract = "Candle-soot nanoparticles (CSNPs) have shown great promise for fabricating optical ultrasound (OpUS) transmitters. They have a facile, inexpensive synthesis whilst their unique, porous structure enables a fast heat diffusion rate which aids high-frequency ultrasound generation necessary for high-resolution clinical imaging. These composites have demonstrated high ultrasoundgeneration performance showing clinically relevant detail, when applied as macroscale OpUS transmitters comprising both concave and planar surfaces, however, less research has been invested into the translation of this material{\textquoteright}s technology to fabricate fiber-optic transmitters for image guidance ofminimally invasive interventions. Here, are reported two fabrication methods of nanocomposites composed of CSNPs embedded within polydimethylsiloxane (PDMS) deposited onto fiber-optic end-faces using two different optimized fabrication methods: “All-in-One” and “Direct Deposition.” Both typesof nanocomposite exhibit a smooth, black domed structure with a maximum dome thickness of 50 µm, broadband optical absorption (>98% between 500 and 1400 nm) and both nanocomposites generated high peak-to-peak ultrasound pressures (>3 MPa) and wide bandwidths (>29 MHz). Further,high-resolution (<40 µm axial resolution) B-mode ultrasound imaging of exvivo lamb brain tissue demonstrating how CSNP-PDMS OpUS transmitters can allow for high fidelity minimally invasive imaging of biological tissues is demonstrated.",

keywords = "brain imaging, candle soot nanoparticles, optical fibers, optical ultrasound, polydimethylsiloxane",

author = "Semyon Bodian and Esra Aytac‐Kipergil and Shaoyan Zhang and India Lewis‐Thompson and Sanjayan Sathasivam and Mathews, {Sunish J.} and Alles, {Erwin J.} and Zhang, {Edward Z.} and Beard, {Paul C.} and Gordon, {Ross J.} and Paul Collier and Parkin, {Ivan P.} and Desjardins, {Adrien E.} and Colchester, {Richard J.} and Sacha Noimark",

year = "2023",

month = mar,

day = "24",

doi = "10.1002/admi.202201792",

language = "English",

volume = "10",

journal = "Advanced Materials Interfaces",

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Bodian, S, Aytac‐Kipergil, E, Zhang, S, Lewis‐Thompson, I, Sathasivam, S, Mathews, SJ, Alles, EJ, Zhang, EZ, Beard, PC, Gordon, RJ, Collier, P, Parkin, IP, Desjardins, AE, Colchester, RJ & Noimark, S 2023, 'Comparison of Fabrication Methods for Fiber-Optic Ultrasound Transmitters Using Candle-Soot Nanoparticles', Advanced Materials Interfaces, vol. 10, no. 9, 2201792. https://doi.org/10.1002/admi.202201792

TY - JOUR

T1 - Comparison of Fabrication Methods for Fiber-Optic Ultrasound Transmitters Using Candle-Soot Nanoparticles

AU - Bodian, Semyon

AU - Aytac‐Kipergil, Esra

AU - Zhang, Shaoyan

AU - Lewis‐Thompson, India

AU - Sathasivam, Sanjayan

AU - Mathews, Sunish J.

AU - Alles, Erwin J.

AU - Zhang, Edward Z.

AU - Beard, Paul C.

AU - Gordon, Ross J.

AU - Collier, Paul

AU - Parkin, Ivan P.

AU - Desjardins, Adrien E.

AU - Colchester, Richard J.

AU - Noimark, Sacha

PY - 2023/3/24

Y1 - 2023/3/24

N2 - Candle-soot nanoparticles (CSNPs) have shown great promise for fabricating optical ultrasound (OpUS) transmitters. They have a facile, inexpensive synthesis whilst their unique, porous structure enables a fast heat diffusion rate which aids high-frequency ultrasound generation necessary for high-resolution clinical imaging. These composites have demonstrated high ultrasoundgeneration performance showing clinically relevant detail, when applied as macroscale OpUS transmitters comprising both concave and planar surfaces, however, less research has been invested into the translation of this material’s technology to fabricate fiber-optic transmitters for image guidance ofminimally invasive interventions. Here, are reported two fabrication methods of nanocomposites composed of CSNPs embedded within polydimethylsiloxane (PDMS) deposited onto fiber-optic end-faces using two different optimized fabrication methods: “All-in-One” and “Direct Deposition.” Both typesof nanocomposite exhibit a smooth, black domed structure with a maximum dome thickness of 50 µm, broadband optical absorption (>98% between 500 and 1400 nm) and both nanocomposites generated high peak-to-peak ultrasound pressures (>3 MPa) and wide bandwidths (>29 MHz). Further,high-resolution (<40 µm axial resolution) B-mode ultrasound imaging of exvivo lamb brain tissue demonstrating how CSNP-PDMS OpUS transmitters can allow for high fidelity minimally invasive imaging of biological tissues is demonstrated.

AB - Candle-soot nanoparticles (CSNPs) have shown great promise for fabricating optical ultrasound (OpUS) transmitters. They have a facile, inexpensive synthesis whilst their unique, porous structure enables a fast heat diffusion rate which aids high-frequency ultrasound generation necessary for high-resolution clinical imaging. These composites have demonstrated high ultrasoundgeneration performance showing clinically relevant detail, when applied as macroscale OpUS transmitters comprising both concave and planar surfaces, however, less research has been invested into the translation of this material’s technology to fabricate fiber-optic transmitters for image guidance ofminimally invasive interventions. Here, are reported two fabrication methods of nanocomposites composed of CSNPs embedded within polydimethylsiloxane (PDMS) deposited onto fiber-optic end-faces using two different optimized fabrication methods: “All-in-One” and “Direct Deposition.” Both typesof nanocomposite exhibit a smooth, black domed structure with a maximum dome thickness of 50 µm, broadband optical absorption (>98% between 500 and 1400 nm) and both nanocomposites generated high peak-to-peak ultrasound pressures (>3 MPa) and wide bandwidths (>29 MHz). Further,high-resolution (<40 µm axial resolution) B-mode ultrasound imaging of exvivo lamb brain tissue demonstrating how CSNP-PDMS OpUS transmitters can allow for high fidelity minimally invasive imaging of biological tissues is demonstrated.

KW - brain imaging

KW - candle soot nanoparticles

KW - optical fibers

KW - optical ultrasound

KW - polydimethylsiloxane

U2 - 10.1002/admi.202201792

DO - 10.1002/admi.202201792

M3 - Article

SN - 2196-7350

VL - 10

JO - Advanced Materials Interfaces

JF - Advanced Materials Interfaces

IS - 9

M1 - 2201792

ER -

Comparison of Fabrication Methods for Fiber-Optic Ultrasound Transmitters Using Candle-Soot Nanoparticles

Abstract

Keywords

UN SDGs

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