Your search keyword '"Collins, Joy E"' showing total 32 results

1. Biodegradable ring-shaped implantable device for intravesical therapy of bladder disorders

Author

Kim, Hyunjoon, Lee, Seung Ho, Wentworth, Adam, Babaee, Sahab, Wong, Kaitlyn, Collins, Joy E., Chu, Jacqueline, Ishida, Keiko, Kuosmanen, Johannes, Jenkins, Joshua, Hess, Kaitlyn, Lopes, Aaron, Morimoto, Joshua, Wan, Qianqian, Potdar, Shaunak V., McNally, Ronan, Tov, Caitlynn, Kim, Na Yoon, Hayward, Alison, Wollin, Daniel, Langer, Robert, and Traverso, Giovanni

Published

2022

2. Oral mRNA delivery using capsule-mediated gastrointestinal tissue injections

Author

Abramson, Alex, Kirtane, Ameya R., Shi, Yunhua, Zhong, Grace, Collins, Joy E., Tamang, Siddartha, Ishida, Keiko, Hayward, Alison, Wainer, Jacob, Rajesh, Netra Unni, Lu, Xiaoya, Gao, Yuan, Karandikar, Paramesh, Tang, Chaoyang, Lopes, Aaron, Wahane, Aniket, Reker, Daniel, Frederiksen, Morten Revsgaard, Jensen, Brian, Langer, Robert, and Traverso, Giovanni

Published

2022

3. Kirigami-inspired stents for sustained local delivery of therapeutics

Author

Babaee, Sahab, Shi, Yichao, Abbasalizadeh, Saeed, Tamang, Siddartha, Hess, Kaitlyn, Collins, Joy E., Ishida, Keiko, Lopes, Aaron, Williams, Michael, Albaghdadi, Mazen, Hayward, Alison M., and Traverso, Giovanni

Published

2021

4. A machine learning liver-on-a-chip system for safer drug formulation

Author

Shi, Yunhua, primary, Lin, Chih-Hsin, additional, Reker, Daniel, additional, Steiger, Christoph, additional, Hess, Kaitlyn, additional, Collins, Joy E., additional, Tamang, Siddartha, additional, Ishida, Keiko, additional, Lopes, Aaron, additional, Wainer, Jacob, additional, Hayward, Alison M., additional, Walesky, Chad, additional, Goessling, Wolfram, additional, and Traverso, Giovanni, additional

Published

2022

5. Ingestible hydrogel device

Author

Massachusetts Institute of Technology. Department of Mechanical Engineering, Koch Institute for Integrative Cancer Research at MIT, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Department of Civil and Environmental Engineering, Liu, Xinyue, Steiger, Christoph Winfried Johannes, Lin, Shaoting, Parada Hernandez, German Alberto, Liu, Ji, Chan, Hon Fai, Yuk, Hyunwoo, Phan, Nhi V, Collins, Joy E, Tamang, Siddartha M, Traverso, Carlo Giovanni, Zhao, Xuanhe, Massachusetts Institute of Technology. Department of Mechanical Engineering, Koch Institute for Integrative Cancer Research at MIT, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Department of Civil and Environmental Engineering, Liu, Xinyue, Steiger, Christoph Winfried Johannes, Lin, Shaoting, Parada Hernandez, German Alberto, Liu, Ji, Chan, Hon Fai, Yuk, Hyunwoo, Phan, Nhi V, Collins, Joy E, Tamang, Siddartha M, Traverso, Carlo Giovanni, and Zhao, Xuanhe

Abstract

© 2019, The Author(s). Devices that interact with living organisms are typically made of metals, silicon, ceramics, and plastics. Implantation of such devices for long-term monitoring or treatment generally requires invasive procedures. Hydrogels offer new opportunities for human-machine interactions due to their superior mechanical compliance and biocompatibility. Additionally, oral administration, coupled with gastric residency, serves as a non-invasive alternative to implantation. Achieving gastric residency with hydrogels requires the hydrogels to swell very rapidly and to withstand gastric mechanical forces over time. However, high swelling ratio, high swelling speed, and long-term robustness do not coexist in existing hydrogels. Here, we introduce a hydrogel device that can be ingested as a standard-sized pill, swell rapidly into a large soft sphere, and maintain robustness under repeated mechanical loads in the stomach for up to one month. Large animal tests support the exceptional performance of the ingestible hydrogel device for long-term gastric retention and physiological monitoring.

Published

2022

6. Respirators in Healthcare: Material, Design, Regulatory, Environmental, and Economic Considerations for Clinical Efficacy

Author

Koch Institute for Integrative Cancer Research at MIT, Massachusetts Institute of Technology. Department of Mechanical Engineering, Young, Cameron C, Byrne, James D, Wentworth, Adam J, Collins, Joy E, Chu, Jacqueline N, Traverso, Giovanni, Koch Institute for Integrative Cancer Research at MIT, Massachusetts Institute of Technology. Department of Mechanical Engineering, Young, Cameron C, Byrne, James D, Wentworth, Adam J, Collins, Joy E, Chu, Jacqueline N, and Traverso, Giovanni

Abstract

Maintaining an ample supply of personal protective equipment continues to be a challenge for the healthcare industry, especially during emergency situations and times of strain on the supply chain. Most critically, healthcare workers exposed to potential airborne hazards require sufficient respiratory protection. Respirators are the only type of personal protective equipment able to provide adequate respiratory protection. However, their ability to shield hazards depends on design, material, proper fit, and environmental conditions. As a result, not all respirators may be adequate for all scenarios. Additionally, factors including user comfort, ease of use, and cost contribute to respirator effectiveness. Therefore, a careful consideration of these parameters is essential for ensuring respiratory protection for those working in the healthcare industry. Here respirator design and material characteristics are reviewed, as well as properties of airborne hazards and potential filtration mechanisms, regulatory standards of governmental agencies, respirator efficacy in the clinical setting, attitude of healthcare personnel toward respiratory protection, and environmental and economic considerations of respirator manufacturing and distribution.

Published

2022

7. 3D‐Printed Gastric Resident Electronics

Author

Massachusetts Institute of Technology. Department of Chemical Engineering, Koch Institute for Integrative Cancer Research at MIT, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Mechanical Engineering, Kong, Yong Lin, Zou, Xingyu, McCandler, Caitlin A, Kirtane, Ameya, Ning, Shen, Zhou, Jianlin, Abid, Abubakar, Jafari, Mousa, Rogner, Jaimie L, Minahan Jr, Daniel J, Collins, Joy E, McDonnell, Shane, Cleveland, Cody, Bensel, Taylor A, Tamang, Siddartha M, Arrick, Graham, Gimbel, Alla, Hua, Tiffany P, Ghosh, Udayan, Soares, Vance, Wang, Nancy, Wahane, Aniket Vijay, Hayward, Alison M, Zhang, Shiyi, Smith, Brian R., Langer, Robert S, Traverso, Carlo Giovanni, Massachusetts Institute of Technology. Department of Chemical Engineering, Koch Institute for Integrative Cancer Research at MIT, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Mechanical Engineering, Kong, Yong Lin, Zou, Xingyu, McCandler, Caitlin A, Kirtane, Ameya, Ning, Shen, Zhou, Jianlin, Abid, Abubakar, Jafari, Mousa, Rogner, Jaimie L, Minahan Jr, Daniel J, Collins, Joy E, McDonnell, Shane, Cleveland, Cody, Bensel, Taylor A, Tamang, Siddartha M, Arrick, Graham, Gimbel, Alla, Hua, Tiffany P, Ghosh, Udayan, Soares, Vance, Wang, Nancy, Wahane, Aniket Vijay, Hayward, Alison M, Zhang, Shiyi, Smith, Brian R., Langer, Robert S, and Traverso, Carlo Giovanni

Abstract

© 2019 The Authors. Published by WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim Long-term implantation of biomedical electronics into the human body enables advanced diagnostic and therapeutic functionalities. However, most long-term resident electronics devices require invasive procedures for implantation as well as a specialized receiver for communication. Here, a gastric resident electronic (GRE) system that leverages the anatomical space offered by the gastric environment to enable residence of an orally delivered platform of such devices within the human body is presented. The GRE is capable of directly interfacing with portable consumer personal electronics through Bluetooth, a widely adopted wireless protocol. In contrast to the passive day-long gastric residence achieved with prior ingestible electronics, advancement in multimaterial prototyping enables the GRE to reside in the hostile gastric environment for a maximum of 36 d and maintain ≈15 d of wireless electronics communications as evidenced by the studies in a porcine model. Indeed, the synergistic integration of reconfigurable gastric-residence structure, drug release modules, and wireless electronics could ultimately enable the next-generation remote diagnostic and automated therapeutic strategies.

Published

2022

8. Personalized Radiation Attenuating Materials for Gastrointestinal Mucosal Protection

Author

Koch Institute for Integrative Cancer Research at MIT, Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Division of Comparative Medicine, Byrne, James D, Young, Cameron C, Chu, Jacqueline N, Pursley, Jennifer, Chen, Mu Xian, Wentworth, Adam J, Feng, Annie, Kirtane, Ameya R, Remillard, Kyla A, Hancox, Cindy I, Bhagwat, Mandar S, Machado, Nicole, Hua, Tiffany, Tamang, Siddartha M, Collins, Joy E, Ishida, Keiko, Hayward, Alison, Becker, Sarah L, Edgington, Samantha K, Schoenfeld, Jonathan D, Jeck, William R, Hur, Chin, Traverso, Giovanni, Koch Institute for Integrative Cancer Research at MIT, Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Division of Comparative Medicine, Byrne, James D, Young, Cameron C, Chu, Jacqueline N, Pursley, Jennifer, Chen, Mu Xian, Wentworth, Adam J, Feng, Annie, Kirtane, Ameya R, Remillard, Kyla A, Hancox, Cindy I, Bhagwat, Mandar S, Machado, Nicole, Hua, Tiffany, Tamang, Siddartha M, Collins, Joy E, Ishida, Keiko, Hayward, Alison, Becker, Sarah L, Edgington, Samantha K, Schoenfeld, Jonathan D, Jeck, William R, Hur, Chin, and Traverso, Giovanni

Abstract

Cancer patients undergoing therapeutic radiation routinely develop injury of the adjacent gastrointestinal (GI) tract mucosa due to treatment. To reduce radiation dose to critical GI structures including the rectum and oral mucosa, 3D-printed GI radioprotective devices composed of high-Z materials are generated from patient CT scans. In a radiation proctitis rat model, a significant reduction in crypt injury is demonstrated with the device compared to without (p < 0.0087). Optimal device placement for radiation attenuation is further confirmed in a swine model. Dosimetric modeling in oral cavity cancer patients demonstrates a 30% radiation dose reduction to the normal buccal mucosa and a 15.2% dose reduction in the rectum for prostate cancer patients with the radioprotectant material in place compared to without. Finally, it is found that the rectal radioprotectant device is more cost-effective compared to a hydrogel rectal spacer. Taken together, these data suggest that personalized radioprotectant devices may be used to reduce GI tissue injury in cancer patients undergoing therapeutic radiation.

Published

2022

9. Kirigami-inspired stents for sustained local delivery of therapeutics

Author

Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Department of Chemical Engineering, Koch Institute for Integrative Cancer Research at MIT, Babaee, Sahab, Shi, Yichao, Abbasalizadeh, Saeed, Tamang, Siddartha, Hess, Kaitlyn, Collins, Joy E, Ishida, Keiko, Lopes, Aaron, Williams, Michael, Albaghdadi, Mazen, Hayward, Alison M, Traverso, Giovanni, Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Department of Chemical Engineering, Koch Institute for Integrative Cancer Research at MIT, Babaee, Sahab, Shi, Yichao, Abbasalizadeh, Saeed, Tamang, Siddartha, Hess, Kaitlyn, Collins, Joy E, Ishida, Keiko, Lopes, Aaron, Williams, Michael, Albaghdadi, Mazen, Hayward, Alison M, and Traverso, Giovanni

Abstract

Implantable drug depots have the capacity to locally meet therapeutic requirements by maximizing local drug efficacy and minimizing potential systemic side effects. Tubular organs including the gastrointestinal tract, respiratory tract and vasculature all manifest with endoluminal disease. The anatomic distribution of localized drug delivery for these organs using existing therapeutic modalities is limited. Application of local depots in a circumferential and extended longitudinal fashion could transform our capacity to offer effective treatment across a range of conditions. Here we report the development and application of a kirigami-based stent platform to achieve this. The stents comprise a stretchable snake-skin-inspired kirigami shell integrated with a fluidically driven linear soft actuator. They have the capacity to deposit drug depots circumferentially and longitudinally in the tubular mucosa of the gastrointestinal tract across millimetre to multi-centimetre length scales, as well as in the vasculature and large airways. We characterize the mechanics of kirigami stents for injection, and their capacity to engage tissue in a controlled manner and deposit degradable microparticles loaded with therapeutics by evaluating these systems ex vivo and in vivo in swine. We anticipate such systems could be applied for a range of endoluminal diseases by simplifying dosing regimens while maximizing drug on-target effects through the sustained release of therapeutics and minimizing systemic side effects.

Published

2022

10. Respirators in Healthcare: Material, Design, Regulatory, Environmental, and Economic Considerations for Clinical Efficacy

Author

Young, Cameron C., primary, Byrne, James D., additional, Wentworth, Adam J., additional, Collins, Joy E., additional, Chu, Jacqueline N., additional, and Traverso, Giovanni, additional

Published

2022

11. Dynamic omnidirectional adhesive microneedle system for oral macromolecular drug delivery

Author

Chen, Wei, primary, Wainer, Jacob, additional, Ryoo, Si Won, additional, Qi, Xiaoyue, additional, Chang, Rong, additional, Li, Jason, additional, Lee, Seung Ho, additional, Min, Seokkee, additional, Wentworth, Adam, additional, Collins, Joy E., additional, Tamang, Siddartha, additional, Ishida, Keiko, additional, Hayward, Alison, additional, Langer, Robert, additional, and Traverso, Giovanni, additional

Published

2022

12. Implantable system for chronotherapy

Author

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

Published

2021

13. Patient and Health Care Worker Perceptions of Communication and Ability to Identify Emotion When Wearing Standard and Transparent Masks

Author

Chu, Jacqueline N., primary, Collins, Joy E., additional, Chen, Tina T., additional, Chai, Peter R., additional, Dadabhoy, Farah, additional, Byrne, James D., additional, Wentworth, Adam, additional, DeAndrea-Lazarus, Ian A., additional, Moreland, Christopher J., additional, Wilson, Jaime A. B., additional, Booth, Alicia, additional, Ghenand, Omkar, additional, Hur, Chin, additional, and Traverso, Giovanni, additional

Published

2021

14. Endoscopically Injectable Shear‐Thinning Hydrogels Facilitating Polyp Removal

Author

Massachusetts Institute of Technology. Department of Chemical Engineering, Koch Institute for Integrative Cancer Research at MIT, Massachusetts Institute of Technology. Division of Comparative Medicine, Harvard University--MIT Division of Health Sciences and Technology, Massachusetts Institute of Technology. Department of Mechanical Engineering, Pang, Yan, Liu, Jinyao, Moussa, Zaina L, Collins, Joy E, McDonnell, Shane, Hayward, Alison M, Jajoo, Kunal, Langer, Robert, Traverso, Giovanni, Massachusetts Institute of Technology. Department of Chemical Engineering, Koch Institute for Integrative Cancer Research at MIT, Massachusetts Institute of Technology. Division of Comparative Medicine, Harvard University--MIT Division of Health Sciences and Technology, Massachusetts Institute of Technology. Department of Mechanical Engineering, Pang, Yan, Liu, Jinyao, Moussa, Zaina L, Collins, Joy E, McDonnell, Shane, Hayward, Alison M, Jajoo, Kunal, Langer, Robert, and Traverso, Giovanni

Abstract

© 2019 The Authors. Published by WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim Submucosal elevation, the process of instilling material in the submucosal space for separation of the surface mucosa and deeper muscularis layer, is a significant aspect of the endoscopic mucosal resection of large lesions performed to facilitate lesion removal and maximize safety. Submucosal injection, when applied, has historically been performed with normal saline, though this is limited by its rapid dissipation; solutions ideally need to be easily injectable, biocompatible, and provide a long-lasting submucosal cushion with a desirable height. Here, reported is a new set of materials, endoscopically injectable shear-thinning hydrogels, meeting these requirements because of their biocompatible components and ability to form a solid hydrogel upon injection. These findings are supported by evaluation in a large animal model and ultimately demonstrate the potential of these shear-thinning hydrogels to serve as efficient submucosal injection fluids for cushion development. Given these unique characteristics, their broad application in mucosal resection techniques is anticipated.

Published

2021

15. 3D‐Printed Gastric Resident Electronics

Author

Kong, Yong Lin, Zou, Xingyu, McCandler, Caitlin A, Kirtane, Ameya R, Ning, Shen, Zhou, Jianlin, Abid, Abubakar, Jafari, Mousa, Rogner, Jaimie, Minahan, Daniel, Collins, Joy E, McDonnell, Shane, Cleveland, Cody, Bensel, Taylor, Tamang, Siid, Arrick, Graham, Gimbel, Alla, Hua, Tiffany, Ghosh, Udayan, Soares, Vance, Wang, Nancy, Wahane, Aniket, Hayward, Alison, Zhang, Shiyi, Smith, Brian R, Langer, Robert, Traverso, Giovanni, Kong, Yong Lin, Zou, Xingyu, McCandler, Caitlin A, Kirtane, Ameya R, Ning, Shen, Zhou, Jianlin, Abid, Abubakar, Jafari, Mousa, Rogner, Jaimie, Minahan, Daniel, Collins, Joy E, McDonnell, Shane, Cleveland, Cody, Bensel, Taylor, Tamang, Siid, Arrick, Graham, Gimbel, Alla, Hua, Tiffany, Ghosh, Udayan, Soares, Vance, Wang, Nancy, Wahane, Aniket, Hayward, Alison, Zhang, Shiyi, Smith, Brian R, Langer, Robert, and Traverso, Giovanni

Abstract

© 2019 The Authors. Published by WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim Long-term implantation of biomedical electronics into the human body enables advanced diagnostic and therapeutic functionalities. However, most long-term resident electronics devices require invasive procedures for implantation as well as a specialized receiver for communication. Here, a gastric resident electronic (GRE) system that leverages the anatomical space offered by the gastric environment to enable residence of an orally delivered platform of such devices within the human body is presented. The GRE is capable of directly interfacing with portable consumer personal electronics through Bluetooth, a widely adopted wireless protocol. In contrast to the passive day-long gastric residence achieved with prior ingestible electronics, advancement in multimaterial prototyping enables the GRE to reside in the hostile gastric environment for a maximum of 36 d and maintain ≈15 d of wireless electronics communications as evidenced by the studies in a porcine model. Indeed, the synergistic integration of reconfigurable gastric-residence structure, drug release modules, and wireless electronics could ultimately enable the next-generation remote diagnostic and automated therapeutic strategies.

Published

2021

16. Assessment of the Acceptability and Feasibility of Using Mobile Robotic Systems for Patient Evaluation

Author

Massachusetts Institute of Technology. Department of Mechanical Engineering, Koch Institute for Integrative Cancer Research at MIT, Chai, Peter, Dadabhoy, Farah Z., Huang, Hen-Wei, Chu, Jacqueline N, Feng, Annie, Le, Hien M., Collins, Joy E, da Silva, Marco, Raibert, Marc, Hur, Chin, Boyer, Edward W., Traverso, Carlo Giovanni, Massachusetts Institute of Technology. Department of Mechanical Engineering, Koch Institute for Integrative Cancer Research at MIT, Chai, Peter, Dadabhoy, Farah Z., Huang, Hen-Wei, Chu, Jacqueline N, Feng, Annie, Le, Hien M., Collins, Joy E, da Silva, Marco, Raibert, Marc, Hur, Chin, Boyer, Edward W., and Traverso, Carlo Giovanni

Abstract

Importance: Before the widespread implementation of robotic systems to provide patient care during the COVID-19 pandemic occurs, it is important to understand the acceptability of these systems among patients and the economic consequences associated with the adoption of robotics in health care settings. Objective: To assess the acceptability and feasibility of using a mobile robotic system to facilitate health care tasks. Design, Setting, and Participants: This study included 2 components: a national survey to examine the acceptability of using robotic systems to perform health care tasks in a hospital setting and a single-site cohort study of patient experiences and satisfaction with the use of a mobile robotic system to facilitate triage and telehealth tasks in the emergency department (ED). The national survey comprised individuals living in the US who participated in a sampling-based survey via an online analytic platform. Participants completed the national survey between August 18 and August 21, 2020. The single-site cohort study included patients living in the US who presented to the ED of a large urban academic hospital providing quaternary care in Boston, Massachusetts between April and August 2020. All data were analyzed from August to October 2020. Exposures: Participants in the national survey completed an online survey to measure the acceptability of using a mobile robotic system to perform health care tasks (facilitating telehealth interviews, acquiring vital signs, obtaining nasal or oral swabs, placing an intravenous catheter, performing phlebotomy, and turning a patient in bed) in a hospital setting in the contexts of general interaction and interaction during the COVID-19 pandemic. Patients in the cohort study were exposed to a mobile robotic system, which was controlled by an ED clinician and used to facilitate a triage interview. After exposure, patients completed an assessment to measure their satisfaction with the robotic system. Main Outcomes, NIH (Grants K23DA044874,T32DK007191-45, R01DA047236), Hans and Mavis Lopater Psychosocial Foundation (Grant R44DA051106)

Published

2021

17. A luminal unfolding microneedle injector for oral delivery of macromolecules

Author

Massachusetts Institute of Technology. Department of Chemistry, Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Division of Comparative Medicine, Massachusetts Institute of Technology. Media Laboratory, Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Biological Engineering, Koch Institute for Integrative Cancer Research at MIT, Abramson, Alex, Caffarel Salvador, Ester, Soares, Vance, Minahan Jr, Daniel J, Tian, Ryan Yu, Lu, Xiaoya, Dellal, David (David M.), Gao, Yuan, Kim, Soyoung, Wainer, Jacob P, Collins, Joy E, Tamang, Siddartha M, Hayward, Alison M, Yoshitake, Tadayuki, Lee, Hsiang-Chieh, Fujimoto, James G, Fels, Johannes, Frederiksen, Morten Revsgaard, Rahbek, Ulrik, Roxhed, Niclas, Langer, Robert S, Traverso, Carlo Giovanni, Massachusetts Institute of Technology. Department of Chemistry, Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Division of Comparative Medicine, Massachusetts Institute of Technology. Media Laboratory, Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Biological Engineering, Koch Institute for Integrative Cancer Research at MIT, Abramson, Alex, Caffarel Salvador, Ester, Soares, Vance, Minahan Jr, Daniel J, Tian, Ryan Yu, Lu, Xiaoya, Dellal, David (David M.), Gao, Yuan, Kim, Soyoung, Wainer, Jacob P, Collins, Joy E, Tamang, Siddartha M, Hayward, Alison M, Yoshitake, Tadayuki, Lee, Hsiang-Chieh, Fujimoto, James G, Fels, Johannes, Frederiksen, Morten Revsgaard, Rahbek, Ulrik, Roxhed, Niclas, Langer, Robert S, and Traverso, Carlo Giovanni

Abstract

Insulin and other injectable biologic drugs have transformed the treatment of patients suffering from diabetes1,2, yet patients and healthcare providers often prefer to use and prescribe less effective orally dosed medications3–5. Compared with subcutaneously administered drugs, oral formulations create less patient discomfort4, show greater chemical stability at high temperatures6, and do not generate biohazardous needle waste7. An oral dosage form for biologic medications is ideal; however, macromolecule drugs are not readily absorbed into the bloodstream through the gastrointestinal tract8. We developed an ingestible capsule, termed the luminal unfolding microneedle injector, which allows for the oral delivery of biologic drugs by rapidly propelling dissolvable drug-loaded microneedles into intestinal tissue using a set of unfolding arms. During ex vivo human and in vivo swine studies, the device consistently delivered the microneedles to the tissue without causing complete thickness perforations. Using insulin as a model drug, we showed that, when actuated, the luminal unfolding microneedle injector provided a faster pharmacokinetic uptake profile and a systemic uptake >10% of that of a subcutaneous injection over a 4-h sampling period. With the ability to load a multitude of microneedle formulations, the device can serve as a platform to orally deliver therapeutic doses of macromolecule drugs., NIH (Grant EB-00244)

Published

2021

18. Temperature-responsive biometamaterials for gastrointestinal applications

Author

Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Massachusetts Institute of Technology. Division of Comparative Medicine, Massachusetts Institute of Technology. Department of Mechanical Engineering, Koch Institute for Integrative Cancer Research at MIT, Babaee, Sahab, Pajovic, Simo, Kirtane, Ameya, Shi, Jiuyun, Caffarel Salvador, Ester, Hess, Kaitlyn, Collins, Joy E, Tamang, Siddartha M, Wahane, Aniket Vijay, Hayward, Alison M, Mazdiyasni, Hormoz, Langer, Robert S, Traverso, Carlo Giovanni, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Massachusetts Institute of Technology. Division of Comparative Medicine, Massachusetts Institute of Technology. Department of Mechanical Engineering, Koch Institute for Integrative Cancer Research at MIT, Babaee, Sahab, Pajovic, Simo, Kirtane, Ameya, Shi, Jiuyun, Caffarel Salvador, Ester, Hess, Kaitlyn, Collins, Joy E, Tamang, Siddartha M, Wahane, Aniket Vijay, Hayward, Alison M, Mazdiyasni, Hormoz, Langer, Robert S, and Traverso, Carlo Giovanni

Abstract

We hypothesized that ingested warm fluids could act as triggers for biomedical devices. We investigated heat dissipation throughout the upper gastrointestinal (GI) tract by administering warm (55°C) water to pigs and identified two zones in which thermal actuation could be applied: esophageal (actuation through warm water ingestion) and extra-esophageal (protected from ingestion of warm liquids and actuatable by endoscopically administered warm fluids). Inspired by a blooming flower, we developed a capsule-sized esophageal system that deploys using elastomeric elements and then recovers its original shape in response to thermal triggering of shape-memory nitinol springs by ingestion of warm water. Degradable millineedles incorporated into the system could deliver model molecules to the esophagus. For the extra-esophageal compartment, we developed a highly flexible macrostructure (mechanical metamaterial) that deforms into a cylindrical shape to safely pass through the esophagus and deploys into a fenestrated spherical shape in the stomach, capable of residing safely in the gastric cavity for weeks. The macrostructure uses thermoresponsive elements that dissociate when triggered with the endoscopic application of warm (55°C) water, allowing safe passage of the components through the GI tract. Our gastric-resident platform acts as a gram-level long-lasting drug delivery dosage form, releasing small-molecule drugs for 2 weeks. We anticipate that temperature-triggered systems could usher the development of the next generation of stents, drug delivery, and sensing systems housed in the GI tract., Bill and Melinda Gates Foundation (Grants OPP1139921 and OPP1139937), NIH (Grant EB000244)

Published

2021

19. Personalized Radiation Attenuating Materials for Gastrointestinal Mucosal Protection

Author

Byrne, James D., primary, Young, Cameron C., additional, Chu, Jacqueline N., additional, Pursley, Jennifer, additional, Chen, Mu Xian, additional, Wentworth, Adam J., additional, Feng, Annie, additional, Kirtane, Ameya R., additional, Remillard, Kyla A., additional, Hancox, Cindy I., additional, Bhagwat, Mandar S., additional, Machado, Nicole, additional, Hua, Tiffany, additional, Tamang, Siddartha M., additional, Collins, Joy E., additional, Ishida, Keiko, additional, Hayward, Alison, additional, Becker, Sarah L., additional, Edgington, Samantha K., additional, Schoenfeld, Jonathan D., additional, Jeck, William R., additional, Hur, Chin, additional, and Traverso, Giovanni, additional

Published

2021

20. Prophylaxis with tetracyclines in ARDS: Potential therapy for COVID-19-induced ARDS?

Author

Byrne, James D., primary, Shakur, Rameen, additional, Collins, Joy E., additional, Becker, Sarah, additional, Young, Cameron C., additional, Boyce, Hannah, additional, and Traverso, Giovanni, additional

Published

2020

21. Sa1527 DEVELOPMENT OF A LONG-ACTING DIRECT-ACTING ANTIVIRAL SYSTEM FOR HEPATITIS C VIRUS TREATMENT IN A SWINE MODEL

Author

Verma, Malvika, primary, Chu, Jacqueline N., additional, Salama, John A., additional, Faiz, Mohammed T., additional, Gwynne, Feyisope Ew Declan, additional, Lopes, Aaron, additional, Hess, Kaitlyn, additional, Soares, Vance, additional, Steiger, Christoph, additional, McManus, Rebecca, additional, Koeppen, Ryan, additional, Hua, Tiffany, additional, Hayward, Alison, additional, Collins, Joy E., additional, Tamang, Siddartha, additional, Ishida, Keiko, additional, Miller, Jonathan B., additional, Katz, Stephanie, additional, Slocum, Alexander H., additional, Sulkowski, Mark, additional, Thomas, David L., additional, Langer, Robert, additional, and Traverso, Giovanni, additional

Published

2020

22. Scalable Gastric Resident Systems for Veterinary Application

Author

Hayward, Alison M, Bensel, Taylor A, Mazdiyasni, Hormoz, Rogner, Jaimie L, Kirtane, Ameya, Lee, Young-Ah, Hua, Tiffany P, Bajpayee, Ambika Goel, Collins, Joy E, McDonnell, Shane, Cleveland, Cody, Lopes, Aaron C, Wahane, Aniket Vijay, Langer, Robert S, Traverso, Carlo Giovanni, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Division of Comparative Medicine, Koch Institute for Integrative Cancer Research at MIT, Hayward, Alison M, Bensel, Taylor A, Mazdiyasni, Hormoz, Rogner, Jaimie L, Kirtane, Ameya, Lee, Young-Ah, Hua, Tiffany P, Bajpayee, Ambika Goel, Collins, Joy E, McDonnell, Shane, Cleveland, Cody, Lopes, Aaron C, Wahane, Aniket Vijay, Langer, Robert S, and Traverso, Carlo Giovanni

Abstract

Gastric resident dosage forms have been used successfully in farm animals for the delivery of a variety of drugs helping address the challenge of extended dosing. Despite these advances, there remains a significant challenge across the range of species with large variation in body size. To address this, we investigate a scalable gastric resident platform capable of prolonged retention. We investigate prototypes in dimensions consistent with administration and retention in the stomachs of two species (rabbit and pig). We investigate sustained gastric retention of our scalable dosage form platform, and in pigs show the capacity to modulate drug release kinetics of a model drug in veterinary practice, meloxicam, with our dosage form. The ability to achieve gastric residence and thereby enable sustained drug levels across different species may have a significant impact in the welfare of animals in both research, agricultural, zoological, and clinical practice settings., Bill & Melinda Gates Foundation (Grant No. OPP1096734), Bill & Melinda Gates Foundation (Grant No. OPP1148627), National Institutes of Health (U.S.) (Grant# EB-000244), Max Planck Society (Research Award, Award Ltr Dtd. 2/11/08), Alexander von Humboldt Foundation, Brigham and Women's Hospital. Division of Gastroenterology, Massachusetts Institute of Technology. Division of Comparative Medicine

Published

2018

23. Development of a long-acting direct-acting antiviral system for hepatitis C virus treatment in swine

Author

Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Tata Center for Technology and Design, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Division of Comparative Medicine, Sloan School of Management, Massachusetts Institute of Technology. Department of Mechanical Engineering, Koch Institute for Integrative Cancer Research at MIT, Verma, Malvika, Chu, Jacqueline N, Salama, John Ashraf Fou, Faiz, Mohammed T., Eweje, Feyisope, Gwynne, Declan A, Lopes, Aaron C, Hess, Kaitlyn, Soares, Vance, Steiger, Christoph Winfried Johannes, McManus, Rebecca S, Koeppen, Ryan P., Hua, Tiffany P, Hayward, Alison M, Collins, Joy E, Tamang, Siddartha M, Ishida, Keiko, Miller, Jonathan B., Katz, Stephanie, Slocum, Alexander H, Sulkowski, Mark S., Thomas, David L., Langer, Robert S, Traverso, Carlo Giovanni, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Tata Center for Technology and Design, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Division of Comparative Medicine, Sloan School of Management, Massachusetts Institute of Technology. Department of Mechanical Engineering, Koch Institute for Integrative Cancer Research at MIT, Verma, Malvika, Chu, Jacqueline N, Salama, John Ashraf Fou, Faiz, Mohammed T., Eweje, Feyisope, Gwynne, Declan A, Lopes, Aaron C, Hess, Kaitlyn, Soares, Vance, Steiger, Christoph Winfried Johannes, McManus, Rebecca S, Koeppen, Ryan P., Hua, Tiffany P, Hayward, Alison M, Collins, Joy E, Tamang, Siddartha M, Ishida, Keiko, Miller, Jonathan B., Katz, Stephanie, Slocum, Alexander H, Sulkowski, Mark S., Thomas, David L., Langer, Robert S, and Traverso, Carlo Giovanni

Abstract

Chronic hepatitis C virus (HCV) infection is a leading cause of cirrhosis worldwide and kills more Americans than 59 other infections, including HIV and tuberculosis, combined. While direct-acting antiviral (DAA) treatments are effective, limited uptake of therapy, particularly in high-risk groups, remains a substantial barrier to eliminating HCV. We developed a long-acting DAA system (LA-DAAS) capable of prolonged dosing and explored its cost-effectiveness. We designed a retrievable coil-shaped LA-DAAS compatible with nasogastric tube administration and the capacity to encapsulate and release gram levels of drugs while resident in the stomach. We formulated DAAs in drug-polymer pills and studied the release kinetics for 1 mo in vitro and in vivo in a swine model. The LA-DAAS was equipped with ethanol and temperature sensors linked via Bluetooth to a phone application to provide patient engagement. We then performed a cost-effectiveness analysis comparing LA-DAAS to DAA alone in various patient groups, including people who inject drugs. Tunable release kinetics of DAAs was enabled for 1 mo with drug-polymer pills in vitro, and the LA-DAAS safely and successfully provided at least month-long release of sofosbuvir in vivo. Temperature and alcohol sensors could interface with external sources for at least 1 mo. The LA-DAAS was cost-effective compared to DAA therapy alone in all groups considered (base case incremental cost-effectiveness ratio $39,800). We believe that the LA-DAA system can provide a cost-effective and patient-centric method for HCV treatment, including in high-risk populations who are currently undertreated., NIH (Grants EB000244 and 5T32DK007191-45)

Published

2020

24. An ingestible bacterial-electronic system to monitor gastrointestinal health

Author

Massachusetts Institute of Technology. Synthetic Biology Center, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Department of Biological Engineering, Koch Institute for Integrative Cancer Research at MIT, Mimee, Mark Kyle, Nadeau, Phillip, Hayward, Alison M, Carim, Sean, Flanagan, Sarah, Jerger, Logan Andrew, Collins, Joy E, McDonnell, Shane, Swartwout, Richard M, Citorik, Robert James, Bulovic, Vladimir, Langer, Robert S, Traverso, Carlo Giovanni, Chandrakasan, Anantha P, Lu, Timothy K, Massachusetts Institute of Technology. Synthetic Biology Center, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Department of Biological Engineering, Koch Institute for Integrative Cancer Research at MIT, Mimee, Mark Kyle, Nadeau, Phillip, Hayward, Alison M, Carim, Sean, Flanagan, Sarah, Jerger, Logan Andrew, Collins, Joy E, McDonnell, Shane, Swartwout, Richard M, Citorik, Robert James, Bulovic, Vladimir, Langer, Robert S, Traverso, Carlo Giovanni, Chandrakasan, Anantha P, and Lu, Timothy K

Abstract

Biomolecular monitoring in the gastrointestinal tract could offer rapid, precise disease detection and management but is impeded by access to the remote and complex environment. Here, we present an ingestible micro-bio-electronic device (IMBED) for in situ biomolecular detection based on environmentally resilient biosensor bacteria and miniaturized luminescence readout electronics that wirelessly communicate with an external device. As a proof of concept, we engineer heme-sensitive probiotic biosensors and demonstrate accurate diagnosis of gastrointestinal bleeding in swine. Additionally, we integrate alternative biosensors to demonstrate modularity and extensibility of the detection platform. IMBEDs enable new opportunities for gastrointestinal biomarker discovery and could transform the management and diagnosis of gastrointestinal disease., Office of Naval Research (Grant N00014-13-1-0424), National Institutes of Health (Grant EB-000244)

Published

2020

25. An ingestible self-orienting system for oral delivery of macromolecules

Author

Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Massachusetts Institute of Technology. Division of Comparative Medicine, Massachusetts Institute of Technology. Media Laboratory, Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Department of Biological Engineering, Koch Institute for Integrative Cancer Research at MIT, Abramson, Alex, Caffarel Salvador, Ester, Khang, Minsoo, Dellal, David, Silverstein, David, Gao, Yuan, Cleveland, Cody, Collins, Joy E, Tamang, Siddartha M, Hayward, Alison M, Roxhed, Niclas, Langer, Robert S, Traverso, Carlo Giovanni, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Massachusetts Institute of Technology. Division of Comparative Medicine, Massachusetts Institute of Technology. Media Laboratory, Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Department of Biological Engineering, Koch Institute for Integrative Cancer Research at MIT, Abramson, Alex, Caffarel Salvador, Ester, Khang, Minsoo, Dellal, David, Silverstein, David, Gao, Yuan, Cleveland, Cody, Collins, Joy E, Tamang, Siddartha M, Hayward, Alison M, Roxhed, Niclas, Langer, Robert S, and Traverso, Carlo Giovanni

Abstract

Biomacromolecules have transformed our capacity to effectively treat diseases; however, their rapid degradation and poor absorption in the gastrointestinal (GI) tract generally limit their administration to parenteral routes. An oral biologic delivery system must aid in both localization and permeation to achieve systemic drug uptake. Inspired by the leopard tortoise’s ability to passively reorient, we developed an ingestible self-orienting millimeter-scale applicator (SOMA) that autonomously positions itself to engage with GI tissue. It then deploys milliposts fabricated from active pharmaceutical ingredients directly through the gastric mucosa while avoiding perforation. We conducted in vivo studies in rats and swine that support the applicator’s safety and, using insulin as a model drug, demonstrated that the SOMA delivers active pharmaceutical ingredient plasma levels comparable to those achieved with subcutaneous millipost administration., National Institutes of Health (U.S.) (grant EB-000244)

Published

2020

26. 3D-Printed Gastric Resident Electronics

Author

Kong, Yong Lin, Zou, Xingyu, McCandler, Caitlin A., Kirtane, Ameya R., Ning, Shen, Zhou, Jianlin, Abid, Abubakar, Jafari, Mousa, Rogner, Jaimie, Minahan, Daniel, Collins, Joy E., McDonnell, Shane, Cleveland, Cody, Bensel, Taylor, Tamang, Siid, Arrick, Graham, Gimbel, Alla, Hua, Tiffany, Ghosh, Udayan, Soares, Vance, Wang, Nancy, Wahane, Aniket, Hayward, Alison, Zhang, Shiyi, Smith, Brian R., Langer, Robert, and Traverso, Giovanni

Subjects

Communication, biomedical devices, ingestible electronics, 3D printing, gastric resident devices, gastric resident electronics

Abstract

Long-term implantation of biomedical electronics into the human body enables advanced diagnostic and therapeutic functionalities. However, most long-term resident electronics devices require invasive procedures for implantation as well as a specialized receiver for communication. Here, a gastric resident electronic (GRE) system that leverages the anatomical space offered by the gastric environment to enable residence of an orally delivered platform of such devices within the human body is presented. The GRE is capable of directly interfacing with portable consumer personal electronics through Bluetooth, a widely adopted wireless protocol. In contrast to the passive day-long gastric residence achieved with prior ingestible electronics, advancement in multimaterial prototyping enables the GRE to reside in the hostile gastric environment for a maximum of 36 d and maintain ≈15 d of wireless electronics communications as evidenced by the studies in a porcine model. Indeed, the synergistic integration of reconfigurable gastric-residence structure, drug release modules, and wireless electronics could ultimately enable the next-generation remote diagnostic and automated therapeutic strategies.

Published

2018

27. Endoscopically Injectable Shear‐Thinning Hydrogels Facilitating Polyp Removal

Author

Pang, Yan, primary, Liu, Jinyao, additional, Moussa, Zaina L., additional, Collins, Joy E., additional, McDonnell, Shane, additional, Hayward, Alison M., additional, Jajoo, Kunal, additional, Langer, Robert, additional, and Traverso, Giovanni, additional

Published

2019

28. Temperature-responsive biometamaterials for gastrointestinal applications

Author

Babaee, Sahab, primary, Pajovic, Simo, additional, Kirtane, Ameya R., additional, Shi, Jiuyun, additional, Caffarel-Salvador, Ester, additional, Hess, Kaitlyn, additional, Collins, Joy E., additional, Tamang, Siddartha, additional, Wahane, Aniket V., additional, Hayward, Alison M., additional, Mazdiyasni, Hormoz, additional, Langer, Robert, additional, and Traverso, Giovanni, additional

Published

2019

29. Scalable Gastric Resident Systems for Veterinary Application

Author

Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Division of Comparative Medicine, Koch Institute for Integrative Cancer Research at MIT, Hayward, Alison M, Bensel, Taylor A, Mazdiyasni, Hormoz, Rogner, Jaimie L, Kirtane, Ameya, Lee, Young-Ah, Hua, Tiffany P, Bajpayee, Ambika Goel, Collins, Joy E, McDonnell, Shane, Cleveland, Cody, Lopes, Aaron C, Wahane, Aniket Vijay, Langer, Robert S, Traverso, Carlo Giovanni, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Division of Comparative Medicine, Koch Institute for Integrative Cancer Research at MIT, Hayward, Alison M, Bensel, Taylor A, Mazdiyasni, Hormoz, Rogner, Jaimie L, Kirtane, Ameya, Lee, Young-Ah, Hua, Tiffany P, Bajpayee, Ambika Goel, Collins, Joy E, McDonnell, Shane, Cleveland, Cody, Lopes, Aaron C, Wahane, Aniket Vijay, Langer, Robert S, and Traverso, Carlo Giovanni

Abstract

Gastric resident dosage forms have been used successfully in farm animals for the delivery of a variety of drugs helping address the challenge of extended dosing. Despite these advances, there remains a significant challenge across the range of species with large variation in body size. To address this, we investigate a scalable gastric resident platform capable of prolonged retention. We investigate prototypes in dimensions consistent with administration and retention in the stomachs of two species (rabbit and pig). We investigate sustained gastric retention of our scalable dosage form platform, and in pigs show the capacity to modulate drug release kinetics of a model drug in veterinary practice, meloxicam, with our dosage form. The ability to achieve gastric residence and thereby enable sustained drug levels across different species may have a significant impact in the welfare of animals in both research, agricultural, zoological, and clinical practice settings., Bill & Melinda Gates Foundation (Grant No. OPP1096734), Bill & Melinda Gates Foundation (Grant No. OPP1148627), National Institutes of Health (U.S.) (Grant# EB-000244), Max Planck Society (Research Award, Award Ltr Dtd. 2/11/08), Alexander von Humboldt Foundation, Brigham and Women's Hospital. Division of Gastroenterology, Massachusetts Institute of Technology. Division of Comparative Medicine

Published

2018

30. 3D‐Printed Gastric Resident Electronics.

Author

Kong, Yong Lin, Zou, Xingyu, McCandler, Caitlin A., Kirtane, Ameya R., Ning, Shen, Zhou, Jianlin, Abid, Abubakar, Jafari, Mousa, Rogner, Jaimie, Minahan, Daniel, Collins, Joy E., McDonnell, Shane, Cleveland, Cody, Bensel, Taylor, Tamang, Siid, Arrick, Graham, Gimbel, Alla, Hua, Tiffany, Ghosh, Udayan, and Soares, Vance

Subjects

MEDICAL electronics

Abstract

Long‐term implantation of biomedical electronics into the human body enables advanced diagnostic and therapeutic functionalities. However, most long‐term resident electronics devices require invasive procedures for implantation as well as a specialized receiver for communication. Here, a gastric resident electronic (GRE) system that leverages the anatomical space offered by the gastric environment to enable residence of an orally delivered platform of such devices within the human body is presented. The GRE is capable of directly interfacing with portable consumer personal electronics through Bluetooth, a widely adopted wireless protocol. In contrast to the passive day‐long gastric residence achieved with prior ingestible electronics, advancement in multimaterial prototyping enables the GRE to reside in the hostile gastric environment for a maximum of 36 d and maintain ≈15 d of wireless electronics communications as evidenced by the studies in a porcine model. Indeed, the synergistic integration of reconfigurable gastric‐residence structure, drug release modules, and wireless electronics could ultimately enable the next‐generation remote diagnostic and automated therapeutic strategies. 3D‐printed orally delivered gastric resident electronic devices allow a needle and surgical‐free synergistic integration of biomedical electronics, the human body, and the digital domain. A maximum gastric residence of 36 and 15.3 d of wireless Bluetooth communication is demonstrated in a hostile gastric environment, enabling the next‐generation remote diagnostic and automated therapeutic strategies. [ABSTRACT FROM AUTHOR]

Published

2019

31. Dynamic omnidirectional adhesive microneedle system for oral macromolecular drug delivery.

Author

Wei Chen, Wainer, Jacob, Si Won Ryoo, Xiaoyue Qi, Rong Chang, Jason Li, Seung Ho Lee, Seokkee Min, Wentworth, Adam, Collins, Joy E., Tamang, Siddartha, Ishida, Keiko, Hayward, Alison, Langer, Robert, and Traverso, Giovanni

Subjects

*ORAL drug administration, *ORAL medication, *MEDICAL personnel, *ACANTHOCEPHALA, *GASTROINTESTINAL system, *GASTRIC mucosa

Abstract

Oral drug administration remains the preferred route for patients and health care providers. Delivery of macromolecules through this route remains challenging because of limitations imposed by the transport across the gastrointestinal epithelium and the dynamic and degradative environment. Here, we present the development of a delivery system that combines physical (microneedle) and nonphysical (enhancer) modes of drug delivery enhancement for a macromolecule in a large animal model. Inspired by the thorny-headed intestinal worm, we report a dynamic omnidirectional mucoadhesive microneedle system capable of prolonged gastric mucosa fixation. Moreover, we incorporate sodium N-[8-(2-hydroxybenzoyl) amino] caprylate along with semaglutide and demonstrate enhanced absorption in swine resistant to physical displacement in the gastric cavity. Meanwhile, we developed a targeted capsule system capable of deploying intact microneedle-containing systems. These systems stand to enable the delivery of a range of drugs through the generation and maintenance of a privileged region in the gastrointestinal tract. [ABSTRACT FROM AUTHOR]

Published

2022

32. Implantable system for chronotherapy.

Author

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

Subjects

*BROMOCRIPTINE, *CLINICAL chronobiology, *NON-alcoholic fatty liver disease, *MYOCARDIAL infarction, *TRANSDERMAL medication, *SOMATOMEDIN C

Abstract

The article presents a study that explores implantable system for chronotherapy. It mentions 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.

Published

2021