Adaptive polymer fiber neural device for drug delivery and enlarged illumination angle for neuromodulation

Research output: Contribution to journalJournal articleResearchpeer-review

Standard

Adaptive polymer fiber neural device for drug delivery and enlarged illumination angle for neuromodulation. / Sui, Kunyang; Meneghetti, Marcello; Kaur, Jaspreet; Sørensen, Roar Jakob Fleng ; Berg, Rune W.; Markos, Christos.

In: Journal of Neural Engineering, Vol. 19, No. 1, 016035, 2022.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Sui, K, Meneghetti, M, Kaur, J, Sørensen, RJF, Berg, RW & Markos, C 2022, 'Adaptive polymer fiber neural device for drug delivery and enlarged illumination angle for neuromodulation', Journal of Neural Engineering, vol. 19, no. 1, 016035. https://doi.org/10.1088/1741-2552/ac5267

APA

Sui, K., Meneghetti, M., Kaur, J., Sørensen, R. J. F., Berg, R. W., & Markos, C. (2022). Adaptive polymer fiber neural device for drug delivery and enlarged illumination angle for neuromodulation. Journal of Neural Engineering, 19(1), [016035]. https://doi.org/10.1088/1741-2552/ac5267

Vancouver

Sui K, Meneghetti M, Kaur J, Sørensen RJF, Berg RW, Markos C. Adaptive polymer fiber neural device for drug delivery and enlarged illumination angle for neuromodulation. Journal of Neural Engineering. 2022;19(1). 016035. https://doi.org/10.1088/1741-2552/ac5267

Author

Sui, Kunyang ; Meneghetti, Marcello ; Kaur, Jaspreet ; Sørensen, Roar Jakob Fleng ; Berg, Rune W. ; Markos, Christos. / Adaptive polymer fiber neural device for drug delivery and enlarged illumination angle for neuromodulation. In: Journal of Neural Engineering. 2022 ; Vol. 19, No. 1.

Bibtex

@article{f99bf0bae5d94e1f959ef2a2cc43cdb4,
title = "Adaptive polymer fiber neural device for drug delivery and enlarged illumination angle for neuromodulation",
abstract = "Objective: Optical fiber devices constitute significant tools for the modulation and interrogation of neuronal circuitry in the mid and deep brain regions. The illuminated brain area during neuromodulation has a direct impact on the spatio-temporal properties of the brain activity and depends solely on the material and geometrical characteristics of the optical fibers. In the present work, we developed two different flexible polymer optical fibers (POFs) with integrated microfluidic channels (MFCs) and an ultra-high numerical aperture (UHNA) for enlarging the illumination angle to achieve efficient neuromodulation.Approach: Three distinct thermoplastic polymers: polysulfone (PSU), polycarbonate (PC), and fluorinated ethylene propylene (FEP) were used to fabricate two step-index UHNA POF neural devices using a scalable thermal drawing process. The POFs were characterized in terms of their illumination map as well as their fluid delivery capability in phantom and adult rat brain slices.Main results: A 100-fold reduced bending stiffness of the proposed fiber devices compared to their commercially available counterparts has been found. The integrated MFCs can controllably deliver dye (trypan blue) on-demand over a wide range of injection rates spanning from 10 nL/min to 1000 nL/min. Compared with commercial silica fibers, the proposed UHNA POFs exhibited an increased illumination area by 17% and 21% under 470 and 650 nm wavelength, respectively. In addition, a fluorescent light recording experiment has been conducted to demonstrate the ability of our UHNA POFs to be used as optical waveguides in fiber photometry.Significance: Our results overcome the current technological limitations of fiber implants that have limited illumination area and we suggest that soft neural fiber devices can be developed using different custom designs for illumination, collection, and photometry applications. We anticipate our work to pave the way towards the development of next-generation functional optical fibers for neuroscience.",
keywords = "Faculty of Health and Medical Sciences, Microfluidic channels, Neural device, Neuromodulation, Polymer optical fibers, Ultra-high numerical aperture, Brain slices, Flexible",
author = "Kunyang Sui and Marcello Meneghetti and Jaspreet Kaur and S{\o}rensen, {Roar Jakob Fleng} and Berg, {Rune W.} and Christos Markos",
year = "2022",
doi = "10.1088/1741-2552/ac5267",
language = "English",
volume = "19",
journal = "Journal of Neural Engineering",
issn = "1741-2560",
publisher = "Institute of Physics Publishing Ltd",
number = "1",

}

RIS

TY - JOUR

T1 - Adaptive polymer fiber neural device for drug delivery and enlarged illumination angle for neuromodulation

AU - Sui, Kunyang

AU - Meneghetti, Marcello

AU - Kaur, Jaspreet

AU - Sørensen, Roar Jakob Fleng

AU - Berg, Rune W.

AU - Markos, Christos

PY - 2022

Y1 - 2022

N2 - Objective: Optical fiber devices constitute significant tools for the modulation and interrogation of neuronal circuitry in the mid and deep brain regions. The illuminated brain area during neuromodulation has a direct impact on the spatio-temporal properties of the brain activity and depends solely on the material and geometrical characteristics of the optical fibers. In the present work, we developed two different flexible polymer optical fibers (POFs) with integrated microfluidic channels (MFCs) and an ultra-high numerical aperture (UHNA) for enlarging the illumination angle to achieve efficient neuromodulation.Approach: Three distinct thermoplastic polymers: polysulfone (PSU), polycarbonate (PC), and fluorinated ethylene propylene (FEP) were used to fabricate two step-index UHNA POF neural devices using a scalable thermal drawing process. The POFs were characterized in terms of their illumination map as well as their fluid delivery capability in phantom and adult rat brain slices.Main results: A 100-fold reduced bending stiffness of the proposed fiber devices compared to their commercially available counterparts has been found. The integrated MFCs can controllably deliver dye (trypan blue) on-demand over a wide range of injection rates spanning from 10 nL/min to 1000 nL/min. Compared with commercial silica fibers, the proposed UHNA POFs exhibited an increased illumination area by 17% and 21% under 470 and 650 nm wavelength, respectively. In addition, a fluorescent light recording experiment has been conducted to demonstrate the ability of our UHNA POFs to be used as optical waveguides in fiber photometry.Significance: Our results overcome the current technological limitations of fiber implants that have limited illumination area and we suggest that soft neural fiber devices can be developed using different custom designs for illumination, collection, and photometry applications. We anticipate our work to pave the way towards the development of next-generation functional optical fibers for neuroscience.

AB - Objective: Optical fiber devices constitute significant tools for the modulation and interrogation of neuronal circuitry in the mid and deep brain regions. The illuminated brain area during neuromodulation has a direct impact on the spatio-temporal properties of the brain activity and depends solely on the material and geometrical characteristics of the optical fibers. In the present work, we developed two different flexible polymer optical fibers (POFs) with integrated microfluidic channels (MFCs) and an ultra-high numerical aperture (UHNA) for enlarging the illumination angle to achieve efficient neuromodulation.Approach: Three distinct thermoplastic polymers: polysulfone (PSU), polycarbonate (PC), and fluorinated ethylene propylene (FEP) were used to fabricate two step-index UHNA POF neural devices using a scalable thermal drawing process. The POFs were characterized in terms of their illumination map as well as their fluid delivery capability in phantom and adult rat brain slices.Main results: A 100-fold reduced bending stiffness of the proposed fiber devices compared to their commercially available counterparts has been found. The integrated MFCs can controllably deliver dye (trypan blue) on-demand over a wide range of injection rates spanning from 10 nL/min to 1000 nL/min. Compared with commercial silica fibers, the proposed UHNA POFs exhibited an increased illumination area by 17% and 21% under 470 and 650 nm wavelength, respectively. In addition, a fluorescent light recording experiment has been conducted to demonstrate the ability of our UHNA POFs to be used as optical waveguides in fiber photometry.Significance: Our results overcome the current technological limitations of fiber implants that have limited illumination area and we suggest that soft neural fiber devices can be developed using different custom designs for illumination, collection, and photometry applications. We anticipate our work to pave the way towards the development of next-generation functional optical fibers for neuroscience.

KW - Faculty of Health and Medical Sciences

KW - Microfluidic channels

KW - Neural device

KW - Neuromodulation

KW - Polymer optical fibers

KW - Ultra-high numerical aperture

KW - Brain slices

KW - Flexible

U2 - 10.1088/1741-2552/ac5267

DO - 10.1088/1741-2552/ac5267

M3 - Journal article

C2 - 35130533

VL - 19

JO - Journal of Neural Engineering

JF - Journal of Neural Engineering

SN - 1741-2560

IS - 1

M1 - 016035

ER -

ID: 290619714