Pierre Daniel Grondin

Works (4)

Updated: April 16th, 2024 05:03

2024 journal article

Use of semi-permeable bag materials to facilitate on-site treatment of biological agent-contaminated waste

WASTE MANAGEMENT, 178, 292–300.

By: P. Lemieux*, A. Touati*, J. Sawyer*, D. Aslett*, S. Serre*, B. Pourdeyhimi n, P. Grondin n, T. McArthur*, A. Abdel-Hady*, M. Monge*

author keywords: Biological incident; Waste management; On -site treatment; Anthrax; Outdoor release
Sources: Web Of Science, ORCID, NC State University Libraries
Added: March 1, 2024

2021 article

Fabrication of drug-loaded ultrafine polymer fibers via solution blowing and their drug release kinetics

49TH SME NORTH AMERICAN MANUFACTURING RESEARCH CONFERENCE (NAMRC 49, 2021), Vol. 53, pp. 128–135.

By: K. Schuchard n, A. Joijode n, V. Willard*, B. Anderson n, P. Grondin n, B. Pourdeyhimi n, R. Shirwaiker n

author keywords: solution blowing; biofabrication; fibers; doxycycline; drug release
Sources: Web Of Science, NC State University Libraries
Added: October 24, 2022

2021 journal article

N-Halamine Polypropylene Nonwoven Fabrics with Rechargeable Antibacterial and Antiviral Functions for Medical Applications

ACS BIOMATERIALS SCIENCE & ENGINEERING, 7(6), 2329–2336.

By: Y. Ma*, N. Wisuthiphaet*, H. Bolt*, N. Nitin*, Q. Zhao*, D. Wang*, B. Pourdeyhimi n, P. Grondin n, G. Sun*

author keywords: polypropylene nonwoven; N-halamine; rechargeable antimicrobial; antiviral; melt graft polymerization
MeSH headings : Amines; Anti-Bacterial Agents / pharmacology; Anti-Infective Agents; Antiviral Agents; Listeria; Polypropylenes
TL;DR: Chlorinated nonwoven fabrics showed a promising antibacterial and antiviral efficiency, achieving 6 log CFU reduction of bacteria and 7 log PFU reductions of a virus within 15 and 5 min of contact, revealing great potential to serve as a reusable antimicrobial material for medical protection applications. (via Semantic Scholar)
UN Sustainable Development Goal Categories
Sources: Web Of Science, NC State University Libraries
Added: July 12, 2021

2020 journal article

High-Throughput Manufacture of 3D Fiber Scaffolds for Regenerative Medicine

TISSUE ENGINEERING PART C-METHODS, 26(7), 364–374.

By: R. Shirwaiker n, M. Fisher n, B. Anderson n, K. Schuchard n, P. Warren n, B. Maze n, P. Grondin n, F. Ligler n, B. Pourdeyhimi n

author keywords: 3D printing; melt blowing; fibers; scaffolds
MeSH headings : Animals; Biocompatible Materials / chemistry; Dogs; Hernia / therapy; Herniorrhaphy / methods; Polymers / chemistry; Printing, Three-Dimensional / instrumentation; Regenerative Medicine; Tissue Engineering / methods; Tissue Scaffolds / chemistry
TL;DR: The 3DMB system described in this study is modified from larger nonwovens manufacturing machinery to accommodate the lower volume, high-cost polymers used for tissue engineering and implantable biomedical devices and has a fiber collection component that uses adaptable robotics to create scaffolds with predetermined geometries. (via Semantic Scholar)
UN Sustainable Development Goal Categories
Sources: Web Of Science, NC State University Libraries
Added: August 10, 2020

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