Point-of-Need Additive Manufacturing in Austere Arctic Environments: An Evaluation of Medical Logistics Requirements and Capabilities Demonstration
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Published:2024-02-28
Issue:3
Volume:11
Page:232
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ISSN:2306-5354
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Container-title:Bioengineering
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language:en
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Short-container-title:Bioengineering
Author:
Wisdom Cate12ORCID, Chartrain Nicholas12ORCID, Blaize-Wise Kelli12, Klarmann George J.12ORCID, Gilchrist Kristin H.12ORCID, Ho Vincent B.13
Affiliation:
1. 4DBio3 Center for Biotechnology, Uniformed Services University of the Health Sciences, 9410 Key West Ave., Suite 150, Rockville, MD 20850, USA 2. The Geneva Foundation, 950 Broadway, Suite 307, Tacoma, WA 98402, USA 3. Department of Radiology and Radiological Sciences, Uniformed Services University of the Health Sciences, 4301 Jones Bridge Road, Bethesda, MD 20814, USA
Abstract
Medical response to military conflicts, natural disasters, and humanitarian crises are challenged by operational logistics with unreliable supply chains, delayed medical evacuation, and compatibility of the disparate medical equipment and consumables. In these environments, stocks of supplies will become more quickly depleted and the need for equipment parts increases secondary to their higher likelihood for failure from overuse. Additive Manufacturing (AM), or 3D printing, at or closer to the point-of-need provides potential solutions to mitigate these logistics challenges. AM’s ability to tailor the resultant product through computer design enables real-time modification of a product to meet a specific situation. In this study, we deployed two different 3D printers to an arctic locale to demonstrate the utility of 3D printing and bioprinting in austere environments. Deployment of AM solutions in austere environments will likely impact medical care following natural disasters and conflicts with contested logistics. The work presented here furthers the readiness status of AM for use in austere environments to manufacture medical equipment parts and demonstrates its potential use for tissue engineering and advanced medical treatments in remote environments.
Funder
Uniformed Services University of the Health Sciences
Reference19 articles.
1. Williams, E., Hudgens, B., and Aten, K. (2022, January 2). Exploring the Potential for 3D Printing in Medical Logistics for Medical Supplies in Operational Environments. Proceedings of the Acquisition Research Program, Virtual. 2. Rasmussen, T.E., Baer, D.G., Doll, B.A., and Caravalho, J. (2024, January 31). In the “Golden Hour”, Army AL&T Magazine, Available online: https://mtec-sc.org/wp-content/uploads/2017/08/ALT-2015-The-Golden-Hour.pdf. 3. (2021). Annual Report 2021, United Nations Office for the Coordination of Humanitarian Affairs (OCHA). 4. Savonen, B., Mahan, T., Curtis, M., Schreier, J., Gershenson, J., and Pearce, J. (2018). Development of a Resilient 3-D Printer for Humanitarian Crisis Response. Technologies, 6. 5. 3D Printing: Applications in Tissue Engineering, Medical Devices, and Drug Delivery;Kumar;AAPS PharmSciTech,2022
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