Implantable system for chronotherapy

Seung Ho Lee; Qianqian Wan; Adam Wentworth; Ian Ballinger; Keiko Ishida; Joy E. Collins; Siddartha Tamang; Hen Wei Huang; Canchen Li; Kaitlyn Hess; Aaron Lopes; Ameya R. Kirtane; Jung Seung Lee; Se Jun Lee; Wei Chen; Kaitlyn Wong; George Selsing; Hyunjoon Kim; Stephen T. Buckley; Alison Hayward; Robert Langer; Giovanni Traverso

doi:10.1126/sciadv.abj4624

Implantable system for chronotherapy

Seung Ho Lee
, Qianqian Wan
, Adam Wentworth
, Ian Ballinger
, Keiko Ishida
, Joy E. Collins
, Siddartha Tamang
, Hen Wei Huang
, Canchen Li
, Kaitlyn Hess
, Aaron Lopes
, Ameya R. Kirtane
, Jung Seung Lee
, Se Jun Lee
, Wei Chen
, Kaitlyn Wong
, George Selsing
, Hyunjoon Kim
, Stephen T. Buckley
, Alison Hayward

Robert Langer, Giovanni Traverso

Department of Biomedical Engineering

Research output: Contribution to journal › Article › peer-review

20 Scopus citations

Abstract

Diurnal variation in enzymes, hormones, and other biological mediators has long been recognized in mammalian physiology. Developments in pharmacobiology over the past few decades have shown that timing drug delivery can enhance drug efficacy. Here, we report the development of a battery-free, refillable, subcutaneous, and trocar-compatible implantable system that facilitates chronotherapy by enabling tight control over the timing of drug administration in response to external mechanical actuation. The external wearable system is coupled to a mobile app to facilitate control over dosing time. Using this system, we show the efficacy of bromocriptine on glycemic control in a diabetic rat model. We also demonstrate that antihypertensives can be delivered through this device, which could have clinical applications given the recognized diurnal variation of hypertension-related complications. We anticipate that implants capable of chronotherapy will have a substantial impact on our capacity to enhance treatment effectiveness for a broad range of chronic conditions.

Original language	English
Article number	eabj4624
Journal	Science Advances
Volume	7
Issue number	48
DOIs	https://doi.org/10.1126/sciadv.abj4624
State	Published - Nov 2021

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Lee, S. H., Wan, Q., Wentworth, A., Ballinger, I., Ishida, K., Collins, J. E., Tamang, S., Huang, H. W., Li, C., Hess, K., Lopes, A., Kirtane, A. R., Lee, J. S., Lee, S. J., Chen, W., Wong, K., Selsing, G., Kim, H., Buckley, S. T., ... Traverso, G. (2021). Implantable system for chronotherapy. Science Advances, 7(48), Article eabj4624. https://doi.org/10.1126/sciadv.abj4624

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title = "Implantable system for chronotherapy",

abstract = "Diurnal variation in enzymes, hormones, and other biological mediators has long been recognized in mammalian physiology. Developments in pharmacobiology over the past few decades have shown that timing drug delivery can enhance drug efficacy. Here, we report the development of a battery-free, refillable, subcutaneous, and trocar-compatible implantable system that facilitates chronotherapy by enabling tight control over the timing of drug administration in response to external mechanical actuation. The external wearable system is coupled to a mobile app to facilitate control over dosing time. Using this system, we show the efficacy of bromocriptine on glycemic control in a diabetic rat model. We also demonstrate that antihypertensives can be delivered through this device, which could have clinical applications given the recognized diurnal variation of hypertension-related complications. We anticipate that implants capable of chronotherapy will have a substantial impact on our capacity to enhance treatment effectiveness for a broad range of chronic conditions.",

author = "Lee, \{Seung Ho\} and Qianqian Wan and Adam Wentworth and Ian Ballinger and Keiko Ishida and Collins, \{Joy E.\} and Siddartha Tamang and Huang, \{Hen Wei\} and Canchen Li and Kaitlyn Hess and Aaron Lopes and Kirtane, \{Ameya R.\} and Lee, \{Jung Seung\} and Lee, \{Se Jun\} and Wei Chen and Kaitlyn Wong and George Selsing and Hyunjoon Kim and Buckley, \{Stephen T.\} and Alison Hayward and Robert Langer and Giovanni Traverso",

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AU - Lee, Seung Ho

AU - Wan, Qianqian

AU - Wentworth, Adam

AU - Ballinger, Ian

AU - Ishida, Keiko

AU - Collins, Joy E.

AU - Tamang, Siddartha

AU - Huang, Hen Wei

AU - Li, Canchen

AU - Hess, Kaitlyn

AU - Lopes, Aaron

AU - Kirtane, Ameya R.

AU - Lee, Jung Seung

AU - Lee, Se Jun

AU - Chen, Wei

AU - Wong, Kaitlyn

AU - Selsing, George

AU - Kim, Hyunjoon

AU - Buckley, Stephen T.

AU - Hayward, Alison

AU - Langer, Robert

AU - Traverso, Giovanni

N1 - Publisher Copyright: Copyright © 2021 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution License 4.0 (CC BY).

PY - 2021/11

Y1 - 2021/11

N2 - Diurnal variation in enzymes, hormones, and other biological mediators has long been recognized in mammalian physiology. Developments in pharmacobiology over the past few decades have shown that timing drug delivery can enhance drug efficacy. Here, we report the development of a battery-free, refillable, subcutaneous, and trocar-compatible implantable system that facilitates chronotherapy by enabling tight control over the timing of drug administration in response to external mechanical actuation. The external wearable system is coupled to a mobile app to facilitate control over dosing time. Using this system, we show the efficacy of bromocriptine on glycemic control in a diabetic rat model. We also demonstrate that antihypertensives can be delivered through this device, which could have clinical applications given the recognized diurnal variation of hypertension-related complications. We anticipate that implants capable of chronotherapy will have a substantial impact on our capacity to enhance treatment effectiveness for a broad range of chronic conditions.

AB - Diurnal variation in enzymes, hormones, and other biological mediators has long been recognized in mammalian physiology. Developments in pharmacobiology over the past few decades have shown that timing drug delivery can enhance drug efficacy. Here, we report the development of a battery-free, refillable, subcutaneous, and trocar-compatible implantable system that facilitates chronotherapy by enabling tight control over the timing of drug administration in response to external mechanical actuation. The external wearable system is coupled to a mobile app to facilitate control over dosing time. Using this system, we show the efficacy of bromocriptine on glycemic control in a diabetic rat model. We also demonstrate that antihypertensives can be delivered through this device, which could have clinical applications given the recognized diurnal variation of hypertension-related complications. We anticipate that implants capable of chronotherapy will have a substantial impact on our capacity to enhance treatment effectiveness for a broad range of chronic conditions.

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AN - SCOPUS:85120376879

SN - 2375-2548

VL - 7

JO - Science Advances

JF - Science Advances

IS - 48

M1 - eabj4624

ER -

Implantable system for chronotherapy

Abstract

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