Your search keyword '"John J. Erickson"' showing total 5 results

1. Tacrolimus exposure windows responsible for Listeria monocytogenes infection susceptibility

Author

John J. Erickson, Hilary Miller-Handley, Sing Sing Way, Emily J. Gregory, Nina Salinger Prasanphanich, and Tzu-Yu Shao

Subjects

Opportunistic infection, Secondary infection, chemical and pharmacologic phenomena, 030230 surgery, medicine.disease_cause, Tacrolimus, Article, Mice, 03 medical and health sciences, 0302 clinical medicine, Listeria monocytogenes, Immunity, medicine, Animals, Humans, Listeriosis, Pathogen, Immunity, Cellular, Transplantation, Attenuated vaccine, business.industry, medicine.disease, Acquired immune system, Mice, Inbred C57BL, surgical procedures, operative, Infectious Diseases, Immunology, 030211 gastroenterology & hepatology, business

Abstract

Tacrolimus is widely used to prevent graft rejection after allogeneic transplantation by suppressing T cells in a non-antigen-specific fashion. Global T cell suppression makes transplant recipients more susceptible to infection, especially infection by opportunistic intracellular pathogens. Infection followed by secondary challenge with the opportunistic intracellular bacterial pathogen, Listeria monocytogenes, was used to probe when tacrolimus most significantly impacts antimicrobial host defense. Tacrolimus treated mice showed no difference in innate susceptibility following primary infection, whereas susceptibility to secondary challenge was significantly increased. Modifying the timing of tacrolimus initiation with respect to primary infection compared with secondary challenge showed significantly reduced susceptibility in tacrolimus treated mice where tacrolimus was discontinued prior to secondary challenge. Thus, tacrolimus overrides protection against secondary infection primed by primary infection (and presumably live attenuated vaccines), with the most critical window for tacrolimus-induced infection susceptibility being exposure immediately prior to secondary challenge. These results have important implications for strategies designed to boost antimicrobial T cell mediated immunity in transplant recipients.

Published

2021

2. MonitoringPlasmodium falciparum growth and development by UV flow cytometry using an optimized Hoechst-thiazole orange staining strategy

Author

John J. Erickson, James W. Jacobberger, Brian T. Grimberg, Peter A. Zimmerman, and R. Michael Sramkoski

Subjects

Erythrocytes, Histology, Ultraviolet Rays, Plasmodium falciparum, Stain, Article, Pathology and Forensic Medicine, Flow cytometry, medicine, Animals, Humans, Parasite hosting, Benzothiazoles, Malaria, Falciparum, Fluorescent Dyes, Life Cycle Stages, medicine.diagnostic_test, biology, Cell Biology, DNA, Protozoan, Flow Cytometry, biology.organism_classification, Molecular biology, Staining, Quinolines, Nucleic acid, biology.protein, Benzimidazoles, Antibody, Cytometry, RNA, Protozoan

Abstract

The complex life cycle of Plasmodium falciparum (Pf) makes it difficult to limit infections and reduce the risk of severe malaria. Improved understanding of Pf blood-stage growth and development would provide new opportunities to evaluate and interfere with successful completion of the parasite's life cycle. Cultured blood stage Pf was incubated with Hoechst 33342 (HO) and thiazole orange (TO) to stain DNA and total nucleic acids, respectively. Correlated HO and TO fluorescence emissions were then measured by flow cytometry. Complex bivariate data patterns were analyzed by manual cluster gating to quantify parasite life cycle stages. The permutations of viable staining with both reagents were tested for optimal detection of parasitized RBC (pRBC). Pf cultures were exposed to HO and TO simultaneously to achieve optimal staining of pRBC and consistent quantification of early and late stages of the replicative cycle (rings through schizonts). Staining of Pf nucleic acids allows for analysis of parasite development in the absence of fixatives, lysis, or radioactivity to enable examination of erythrocytes from parasite invasion through schizont rupture using sensitive and rapid assay procedures. Investigation of the mechanisms by which anti-malarial drugs and antibodies act against different Pf lifecycle stages will be aided by this cytometric strategy. © 2008 International Society for Advancement of Cytometry

Published

2008

3. Driving adoption of new technologies in biopharmaceutical manufacturing.

Author

Schaefer G, Balchunas J, Charlebois T, Erickson J, Hart R, Kedia SB, and Lee KH

Subjects

Humans, Technology, Drug Industry, Biological Products

Abstract

The challenge of introducing new technologies into established industries is not a problem unique to the biopharmaceutical industry. However, it may be critical to the long-term competitiveness of individual manufacturers and, more importantly, the ability to deliver therapies to patients. This is especially true for new treatment modalities including cell and gene therapies. We review several barriers to technology adoption which have been identified in various public forums including business, regulatory, technology, and people-driven concerns. We also summarize suitable enablers addressing one or more of these barriers along with suggestions for developing synergies or connections between innovation in product discovery and manufacturing or across the supplier, discovery, manufacturing, and regulatory arms of the holistic innovation engine., (© 2023 The Authors. Biotechnology and Bioengineering published by Wiley Periodicals LLC.)

Published

2023

4. Biomanufacturing readiness levels [BRL]-A shared vocabulary for biopharmaceutical technology development and commercialization.

Author

Kedia SB, Baker JC, Carbonell RG, Lee KH, Roberts CJ, Erickson J, Schiel JE, Rogers K, Schaefer G, and Pluschkell S

Subjects

Industrial Development, Vocabulary, Technology, Biological Products

Abstract

The Manufacturing Readiness Levels (MRLs) developed by the Department of Defense are well-established tools for describing the maturity of new technologies resulting from government-sponsored Research and Development programs, from the concept phase to commercial deployment. While MRLs are generally applicable to a wide range of industries and technologies, there is significant value in offering an industry-specific view on how the basic principles may be applied to biomanufacturing. This paper describes Biomanufacturing Readiness Levels (BRLs) developed by the National Institute for Innovation in Manufacturing Biopharmaceuticals (NIIMBL), a public/private partnership that is part of the Manufacturing USA network. NIIMBL brings together private, federal, nonprofit, and academic stakeholders to accelerate the deployment of innovative technologies for biopharmaceutical production and to educate and train a world-leading biomanufacturing workforce. We anticipate that these BRLs will lay the groundwork for a shared vocabulary for assessment of technology maturity and readiness for commercial biomanufacturing that effectively meets the needs of this critical, specialized, and highly regulated industry., (© 2022 The Authors. Biotechnology and Bioengineering published by Wiley Periodicals LLC.)

Published

2022

5. End-to-end collaboration to transform biopharmaceutical development and manufacturing.

Author

Erickson J, Baker J, Barrett S, Brady C, Brower M, Carbonell R, Charlebois T, Coffman J, Connell-Crowley L, Coolbaugh M, Fallon E, Garr E, Gillespie C, Hart R, Haug A, Nyberg G, Phillips M, Pollard D, Qadan M, Ramos I, Rogers K, Schaefer G, Walther J, and Lee K

Subjects

Quality Control, Biological Products, Drug Industry, Technology, Pharmaceutical

Abstract

An ambitious 10-year collaborative program is described to invent, design, demonstrate, and support commercialization of integrated biopharmaceutical manufacturing technology intended to transform the industry. Our goal is to enable improved control, robustness, and security of supply, dramatically reduced capital and operating cost, flexibility to supply an extremely diverse and changing portfolio of products in the face of uncertainty and changing demand, and faster product development and supply chain velocity, with sustainable raw materials, components, and energy use. The program is organized into workstreams focused on end-to-end control strategy, equipment flexibility, next generation technology, sustainability, and a physical test bed to evaluate and demonstrate the technologies that are developed. The elements of the program are synergistic. For example, process intensification results in cost reduction as well as increased sustainability. Improved robustness leads to less inventory, which improves costs and supply chain velocity. Flexibility allows more products to be consolidated into fewer factories, reduces the need for new facilities, simplifies the acquisition of additional capacity if needed, and reduces changeover time, which improves cost and velocity. The program incorporates both drug substance and drug product manufacturing, but this paper will focus on the drug substance elements of the program., (© 2021 The Authors. Biotechnology and Bioengineering published by Wiley Periodicals LLC.)

Published

2021