Your search keyword '"Ikeda Trashi"' showing total 8 results

1. Self-assembly of a fluorescent virus-like particle for imaging in tissues with high autofluorescence

Author

Ikeda Trashi, Mateusz Z. Durbacz, Orikeda Trashi, Yalini H. Wijesundara, Ryanne N. Ehrman, Alyssa C. Chiev, Cary B. Darwin, Fabian C. Herbert, Jashkaran Gadhvi, Nicole J. De Nisco, Steven O. Nielsen, and Jeremiah J. Gassensmith

Subjects

Biomedical Engineering, General Materials Science, General Chemistry, General Medicine

Abstract

Qβ VLP simplified assembly approach uses the positively charged Rev tag to interact electrostatically with the negatively charged RNAs. This system exploits the known hairpins produced in the coat protein sequence to template the assembly of the full viral capsid.

Published

2023

2. In vivo biocompatibility of ZIF-8 for slow release via intranasal administration

Author

Sneha Kumari, Thomas S. Howlett, Ryanne N. Ehrman, Shailendra Koirala, Orikeda Trashi, Ikeda Trashi, Yalini H. Wijesundara, and Jeremiah J. Gassensmith

Subjects

General Chemistry

Abstract

Studying the toxicity of zeolitic imidazolate framework-8 (ZIF-8) in context of intranasal administration will help researchers in building depot platforms for this non-invasive route of delivery.

Published

2023

3. Rip it, stitch it, click it: A Chemist's guide to VLP manipulation

Author

Yalini H. Wijesundara, Fabian C. Herbert, Sneha Kumari, Thomas Howlett, Shailendra Koirala, Orikeda Trashi, Ikeda Trashi, Noora M. Al-Kharji, and Jeremiah J. Gassensmith

Subjects

Virology

Abstract

Viruses are some of nature's most ubiquitous self-assembled molecular containers. Evolutionary pressures have created some incredibly robust, thermally, and enzymatically resistant carriers to transport delicate genetic information safely. Virus-like particles (VLPs) are human-engineered non-infectious systems that inherit the parent virus' ability to self-assemble under controlled conditions while being non-infectious. VLPs and plant-based viral nanoparticles are becoming increasingly popular in medicine as their self-assembly properties are exploitable for applications ranging from diagnostic tools to targeted drug delivery. Understanding the basic structure and principles underlying the assembly of higher-order structures has allowed researchers to disassemble (rip it), reassemble (stitch it), and functionalize (click it) these systems on demand. This review focuses on the current toolbox of strategies developed to manipulate these systems by ripping, stitching, and clicking to create new technologies in the biomedical space.

Published

2022

4. Biolistic delivery of liposomes protected in metal-organic frameworks

Author

Sneha Kumari, Yalini H. Wijesundara, Thomas S. Howlett, Mohammad Waliullah, Fabian C. Herbert, Arun Raja, Ikeda Trashi, Rodrigo A. Bernal, and Jeremiah J. Gassensmith

Subjects

Multidisciplinary

Abstract

Needle-and-syringe-based delivery has been the commercial standard for vaccine administration to date. With worsening medical personnel availability, increasing biohazard waste production, and the possibility of cross-contamination, we explore the possibility of biolistic delivery as an alternate skin-based delivery route. Delicate formulations like liposomes are inherently unsuitable for this delivery model as they are fragile biomaterials incapable of withstanding shear stress and are exceedingly difficult to formulate as a lyophilized powder for room temperature storage. Here we have developed a approach to deliver liposomes into the skin biolistically—by encapsulating them in a nano-sized shell made of Zeolitic Imidazolate Framework-8 (ZIF-8). When encapsulated within a crystalline and rigid coating, the liposomes are not only protected from thermal stress, but also shear stress. This protection from stressors is crucial, especially for formulations with cargo encapsulated inside the lumen of the liposomes. Moreover, the coating provides the liposomes with a solid exterior that allows the particles to penetrate the skin effectively. In this work, we explored the mechanical protection ZIF-8 provides to liposomes as a preliminary investigation for using biolistic delivery as an alternative to syringe-and-needle–based delivery of vaccines. We demonstrated that liposomes with a variety of surface charges could be coated with ZIF-8 using the right conditions, and this coating can be just as easily removed—without causing any damage to the protected material. The protective coating prevented the liposomes from leaking cargo and helped in their effective penetration when delivered into the agarose tissue model and porcine skin tissue.

Published

2023

5. Carrier gas triggered controlled biolistic delivery of DNA and protein therapeutics from metal–organic frameworks

Author

Yalini H. Wijesundara, Fabian C. Herbert, Orikeda Trashi, Ikeda Trashi, Olivia R. Brohlin, Sneha Kumari, Thomas Howlett, Candace E. Benjamin, Arezoo Shahrivarkevishahi, Shashini D. Diwakara, Sachini D. Perera, Samuel A. Cornelius, Juan P. Vizuet, Kenneth J. Balkus, Ronald A. Smaldone, Nicole J. De Nisco, and Jeremiah J. Gassensmith

Subjects

General Chemistry

Abstract

The efficacy and specificity of protein, DNA, and RNA-based drugs have made them popular in the clinic; however, their susceptibility to environmental stressors adds significant challenges to formulating biomacromolecules into delivery systems where the kinetics of release can be tuned. Further, these drugs are often delivered via injection, which requires skilled medical personnel and produces biohazardous waste. Here, we report an approach that allows for the controlled delivery of DNA and protein therapeutics to allow for either burst or slow-release kinetics without altering the formulation; further, we show we can deliver these materials into the tissues of very different organisms without the use of needles. We show that biomaterials encapsulated within the highly porous metal-organic Framework ZIF-8 are stable as a powder formulation that can be shot into tissue with a low-cost gas-powered “MOF-Jet” for direct delivery into living tissues of plants and animals and the release of the biomaterials can be controlled by judiciously choosing the compressed gas used in the gun. Many MOFs, including ZIF-8, are acid labile and readily dissolve at low pH. When CO2 is used as the carrier gas to shoot MOFs into moist tissue, we show that we can create a transient and weakly acidic local environment that causes the near-instantaneous release of the biomolecules. Conversely, when air is used, the MOF is delivered into tissue and degrades slowly over a week, releasing biomolecules. This innovation represents the first example of biolistic-mediated controlled delivery of biomolecules with ZIF-8 and provides a powerful tool for fundamental and applied plant and animal sciences research.

Published

2022

6. In VivoBiocompatibility of ZIF-8 for Slow Release via Intranasal Administration

Author

Sneha Kumari, Thomas S. Howlett, Ryanne N. Ehrman, Shailendra Koirala, Orikeda Trashi, Ikeda Trashi, Yalini H. Wijesundara, and Jeremiah J. Gassensmith

Abstract

Zeolitic Imidazolate Framework-8 (ZIF-8) is becoming popular in research for its potential in antigen protection and for providing a thermally stable, slow-release platform. While papers applying these materials for immunological applications are aplenty in literature, studies that explore the biosafety of ZIF-8 in mammals—especially when administered intranasally—are not well represented. We checked the body clearance of uncoated and ZIF-coated liposomes and observed that the release slowed as ZIF-8 is easily degraded by mucosal fluid in the nasal cavity. We delivered varying doses of ZIF-8, checked their short- and long-term effects on diagnostic proteins found in blood serum, and found no noticeable differences from the saline control group. We also studied their lung diffusing capacity and tissue morphology; neither showed significant changes in morphology or function.Abstract FigureGraphical Abstract:General overview of the investigation

Published

2023

7. Biolistic Delivery of MOF-Protected Liposomes

Author

Sneha Kumari, Yalini H. Wijesundara, Thomas S. Howlett, Fabian C. Herbert, Arun Raja, Ikeda Trashi, Jashkaran Gadhvi, Nicole J. De Nisco, and Jeremiah Gassensmith

Abstract

Needle-and-syringe-based delivery has been the commercial standard for vaccine administration to date. With worsening medical personnel availability, increasing biohazard waste production, and the possibility of cross-contamination, we explore the possibility of biolistic delivery as an alternate skin-based delivery route. Delicate formulations like liposomes are inherently unsuitable for this delivery model as they are delicate biomaterials incapable of withstanding shear stress. When encapsulated within a crystalline and rigid coating made of zeolitic imidazolate frameworks, the liposomes are not only protected from thermal stress but also shear stress. The protection from shear stress is crucial, especially for formulations with cargo encapsulated inside the lumen of the liposomes. Moreover, the coating provides the liposomes a solid, rigid exterior which allows the particles to penetrate the tissue model and porcine tissue effectively.

Published

2022

8. Rip It, Stitch It, Click It: A Chemist’s Guide to VLP Manipulation

Author

Fabian C Herbert, Yalini H Wijesundara, Sneha Kumari, Thomas Howlett, Shailendra Koirala, Orikeda Trashi, Ikeda Trashi, Noora M. Al-Kharji, and Jeremiah Gassensmith

Abstract

Viruses are some of nature’s most ubiquitous self-assembled molecular containers. Evolutionary pressures have created some incredibly robust, thermally and enzymatically resistant containers to transport delicate genetic information safely. Virus-like particles (VLPs) are human-engineered non-infectious systems that inherit the parent virus’ ability to self-assemble under controlled conditions while being non-infectious. VLPs and plant-based viral nanoparticles are becoming increasingly popular in medicine as their self-assembly properties are exploitable for applications ranging from diagnostic tools to targeted drug delivery. Understanding the basic structure and principles underlying the assembly of higher-order structures has allowed researchers to disassemble (rip it), functionalize (click it), and reassemble (stitch it) these systems on demand. This review focuses on the current toolbox of strategies developed to manipulate these systems by ripping, stitching, and clicking to create new technologies in the biomedical space.

Published

2022