Dynamic actuation enhances transport and extends therapeutic lifespan in an implantable drug delivery platform

William Whyte; Debkalpa Goswami; Sophie X. Wang; Yiling Fan; Niamh A. Ward; Ruth E. Levey; Rachel Beatty; Scott T. Robinson; Declan Sheppard; Raymond O’Connor; David S. Monahan; Lesley Trask; Keegan L. Mendez; Claudia E. Varela; Markus A. Horvath; Robert Wylie; Joanne O'Dwyer; Daniel A. Domingo-Lopez; Arielle S. Rothman; Garry P. Duffy; Eimear B. Dolan; Ellen T. Roche

doi:10.1038/s41467-022-32147-w

Dynamic actuation enhances transport and extends therapeutic lifespan in an implantable drug delivery platform

William Whyte
, Debkalpa Goswami
, Sophie X. Wang
, Yiling Fan
, Niamh A. Ward
, Ruth E. Levey
, Rachel Beatty
, Scott T. Robinson
, Declan Sheppard
, Raymond O’Connor
, David S. Monahan
, Lesley Trask
, Keegan L. Mendez
, Claudia E. Varela
, Markus A. Horvath
, Robert Wylie
, Joanne O'Dwyer
, Daniel A. Domingo-Lopez
, Arielle S. Rothman
, Garry P. Duffy

Eimear B. Dolan, Ellen T. Roche

Research output: Contribution to a Journal (Peer & Non Peer) › Article › peer-review

32 Citations (Scopus)

Abstract

Fibrous capsule (FC) formation, secondary to the foreign body response (FBR), impedes molecular transport and is detrimental to the long-term efficacy of implantable drug delivery devices, especially when tunable, temporal control is necessary. We report the development of an implantable mechanotherapeutic drug delivery platform to mitigate and overcome this host immune response using two distinct, yet synergistic soft robotic strategies. Firstly, daily intermittent actuation (cycling at 1 Hz for 5 minutes every 12 hours) preserves long-term, rapid delivery of a model drug (insulin) over 8 weeks of implantation, by mediating local immunomodulation of the cellular FBR and inducing multiphasic temporal FC changes. Secondly, actuation-mediated rapid release of therapy can enhance mass transport and therapeutic effect with tunable, temporal control. In a step towards clinical translation, we utilise a minimally invasive percutaneous approach to implant a scaled-up device in a human cadaveric model. Our soft actuatable platform has potential clinical utility for a variety of indications where transport is affected by fibrosis, such as the management of type 1 diabetes.

Original language	English
Article number	4496
Pages (from-to)	4496
Journal	Nature Communications
Volume	13
Issue number	1
DOIs	https://doi.org/10.1038/s41467-022-32147-w
Publication status	Published - 3 Aug 2022

Keywords

Drug Delivery Systems
Fibrosis
Foreign-Body Reaction
Humans
Longevity
Prostheses and Implants

UN SDGs

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

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10.1038/s41467-022-32147-w

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Whyte, W., Goswami, D., Wang, S. X., Fan, Y., Ward, N. A., Levey, R. E., Beatty, R., Robinson, S. T., Sheppard, D., O’Connor, R., Monahan, D. S., Trask, L., Mendez, K. L., Varela, C. E., Horvath, M. A., Wylie, R., O'Dwyer, J., Domingo-Lopez, D. A., Rothman, A. S., ... Roche, E. T. (2022). Dynamic actuation enhances transport and extends therapeutic lifespan in an implantable drug delivery platform. Nature Communications, 13(1), 4496. Article 4496. https://doi.org/10.1038/s41467-022-32147-w

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title = "Dynamic actuation enhances transport and extends therapeutic lifespan in an implantable drug delivery platform",

abstract = "Fibrous capsule (FC) formation, secondary to the foreign body response (FBR), impedes molecular transport and is detrimental to the long-term efficacy of implantable drug delivery devices, especially when tunable, temporal control is necessary. We report the development of an implantable mechanotherapeutic drug delivery platform to mitigate and overcome this host immune response using two distinct, yet synergistic soft robotic strategies. Firstly, daily intermittent actuation (cycling at 1 Hz for 5 minutes every 12 hours) preserves long-term, rapid delivery of a model drug (insulin) over 8 weeks of implantation, by mediating local immunomodulation of the cellular FBR and inducing multiphasic temporal FC changes. Secondly, actuation-mediated rapid release of therapy can enhance mass transport and therapeutic effect with tunable, temporal control. In a step towards clinical translation, we utilise a minimally invasive percutaneous approach to implant a scaled-up device in a human cadaveric model. Our soft actuatable platform has potential clinical utility for a variety of indications where transport is affected by fibrosis, such as the management of type 1 diabetes.",

keywords = "Drug Delivery Systems, Fibrosis, Foreign-Body Reaction, Humans, Longevity, Prostheses and Implants",

author = "William Whyte and Debkalpa Goswami and Wang, \{Sophie X.\} and Yiling Fan and Ward, \{Niamh A.\} and Levey, \{Ruth E.\} and Rachel Beatty and Robinson, \{Scott T.\} and Declan Sheppard and Raymond O{\textquoteright}Connor and Monahan, \{David S.\} and Lesley Trask and Mendez, \{Keegan L.\} and Varela, \{Claudia E.\} and Horvath, \{Markus A.\} and Robert Wylie and Joanne O'Dwyer and Domingo-Lopez, \{Daniel A.\} and Rothman, \{Arielle S.\} and Duffy, \{Garry P.\} and Dolan, \{Eimear B.\} and Roche, \{Ellen T.\}",

note = "{\textcopyright} 2022. The Author(s).",

year = "2022",

month = aug,

day = "3",

doi = "10.1038/s41467-022-32147-w",

language = "English",

volume = "13",

pages = "4496",

journal = "Nature Communications",

issn = "2041-1723",

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Whyte, W, Goswami, D, Wang, SX, Fan, Y, Ward, NA, Levey, RE, Beatty, R, Robinson, ST, Sheppard, D, O’Connor, R, Monahan, DS, Trask, L, Mendez, KL, Varela, CE, Horvath, MA, Wylie, R, O'Dwyer, J, Domingo-Lopez, DA, Rothman, AS, Duffy, GP , Dolan, EB & Roche, ET 2022, 'Dynamic actuation enhances transport and extends therapeutic lifespan in an implantable drug delivery platform', Nature Communications, vol. 13, no. 1, 4496, pp. 4496. https://doi.org/10.1038/s41467-022-32147-w

TY - JOUR

T1 - Dynamic actuation enhances transport and extends therapeutic lifespan in an implantable drug delivery platform

AU - Whyte, William

AU - Goswami, Debkalpa

AU - Wang, Sophie X.

AU - Fan, Yiling

AU - Ward, Niamh A.

AU - Levey, Ruth E.

AU - Beatty, Rachel

AU - Robinson, Scott T.

AU - Sheppard, Declan

AU - O’Connor, Raymond

AU - Monahan, David S.

AU - Trask, Lesley

AU - Mendez, Keegan L.

AU - Varela, Claudia E.

AU - Horvath, Markus A.

AU - Wylie, Robert

AU - O'Dwyer, Joanne

AU - Domingo-Lopez, Daniel A.

AU - Rothman, Arielle S.

AU - Duffy, Garry P.

AU - Dolan, Eimear B.

AU - Roche, Ellen T.

PY - 2022/8/3

Y1 - 2022/8/3

N2 - Fibrous capsule (FC) formation, secondary to the foreign body response (FBR), impedes molecular transport and is detrimental to the long-term efficacy of implantable drug delivery devices, especially when tunable, temporal control is necessary. We report the development of an implantable mechanotherapeutic drug delivery platform to mitigate and overcome this host immune response using two distinct, yet synergistic soft robotic strategies. Firstly, daily intermittent actuation (cycling at 1 Hz for 5 minutes every 12 hours) preserves long-term, rapid delivery of a model drug (insulin) over 8 weeks of implantation, by mediating local immunomodulation of the cellular FBR and inducing multiphasic temporal FC changes. Secondly, actuation-mediated rapid release of therapy can enhance mass transport and therapeutic effect with tunable, temporal control. In a step towards clinical translation, we utilise a minimally invasive percutaneous approach to implant a scaled-up device in a human cadaveric model. Our soft actuatable platform has potential clinical utility for a variety of indications where transport is affected by fibrosis, such as the management of type 1 diabetes.

AB - Fibrous capsule (FC) formation, secondary to the foreign body response (FBR), impedes molecular transport and is detrimental to the long-term efficacy of implantable drug delivery devices, especially when tunable, temporal control is necessary. We report the development of an implantable mechanotherapeutic drug delivery platform to mitigate and overcome this host immune response using two distinct, yet synergistic soft robotic strategies. Firstly, daily intermittent actuation (cycling at 1 Hz for 5 minutes every 12 hours) preserves long-term, rapid delivery of a model drug (insulin) over 8 weeks of implantation, by mediating local immunomodulation of the cellular FBR and inducing multiphasic temporal FC changes. Secondly, actuation-mediated rapid release of therapy can enhance mass transport and therapeutic effect with tunable, temporal control. In a step towards clinical translation, we utilise a minimally invasive percutaneous approach to implant a scaled-up device in a human cadaveric model. Our soft actuatable platform has potential clinical utility for a variety of indications where transport is affected by fibrosis, such as the management of type 1 diabetes.

KW - Drug Delivery Systems

KW - Fibrosis

KW - Foreign-Body Reaction

KW - Humans

KW - Longevity

KW - Prostheses and Implants

UR - https://www.scopus.com/pages/publications/85135281193

U2 - 10.1038/s41467-022-32147-w

DO - 10.1038/s41467-022-32147-w

M3 - Article

C2 - 35922421

SN - 2041-1723

VL - 13

SP - 4496

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 4496

ER -

Dynamic actuation enhances transport and extends therapeutic lifespan in an implantable drug delivery platform

Abstract

Keywords

UN SDGs

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