Your search keyword '"Desai, Tejal A."' showing total 11 results

1. Nanotopography Enhances Dynamic Remodeling of Tight Junction Proteins through Cytosolic Liquid Complexes

Author

Huang, Xiao, Shi, Xiaoyu, Hansen, Mollie Eva, Setiady, Initha, Nemeth, Cameron L, Celli, Anna, Huang, Bo, Mauro, Theodora, Koval, Michael, and Desai, Tejal A

Subjects

1.1 Normal biological development and functioning, Underpinning research, Actin Cytoskeleton, Epithelial Cells, Permeability, Phosphoproteins, Tight Junction Proteins, Tight Junctions, Zonula Occludens-1 Protein, nanotopography, tight junction, dynamic remodeling, cytosoltc complex, paracellular permeability, cytosolic complex, Nanoscience & Nanotechnology

Abstract

Nanotopographic materials provide special biophysical stimuli that can regulate epithelial tight junctions and their barrier function. Through the use of total internal reflection fluorescence microscopy of live cells, we demonstrated that contact of synthetic surfaces with defined nanotopography at the apical surface of epithelial monolayers increased paracellular permeability of macromolecules. To monitor changes in tight junction morphology in live cells, we fluorescently tagged the scaffold protein zonula occludens-1 (ZO-1) through CRISPR/Cas9-based gene editing to enable live cell tracking of ZO-1 expressed at physiologic levels. Contact between cells and nanostructured surfaces destabilized junction-associated ZO-1 and promoted its arrangement into highly dynamic liquid cytosolic complexes with a 1-5 μm diameter. Junction-associated ZO-1 rapidly remodeled, and we observed the direct transformation of cytosolic complexes into junction-like structures. Claudin-family tight junction transmembrane proteins and F-actin also were associated with these ZO-1 containing cytosolic complexes. These data suggest that these cytosolic structures are important intermediates formed in response to nanotopographic cues that facilitate rapid tight junction remodeling in order to regulate paracellular permeability.

Published

2020

2. Nanoporous Immunoprotective Device for Stem-Cell-Derived β-Cell Replacement Therapy.

Author

Chang, Ryan, Faleo, Gaetano, Russ, Holger, Parent, Audrey, Elledge, Susanna, Desai, Tejal, Allen, Jessica, Villanueva, Karina, Hebrok, Matthias, Tang, Qizhi, and Bernards, Daniel

Subjects

cell encapsulation device, cell therapy, diabetes, immunoengineering, nanotechnology, Animals, Cell Survival, Cell- and Tissue-Based Therapy, Mice, Nanostructures, Nanotechnology, Peritoneal Cavity, Polymers, Stem Cell Transplantation, Teratoma

Abstract

Encapsulation of human embryonic stem-cell-differentiated beta cell clusters (hES-βC) holds great promise for cell replacement therapy for the treatment of diabetics without the need for chronic systemic immune suppression. Here, we demonstrate a nanoporous immunoprotective polymer thin film cell encapsulation device that can exclude immune molecules while allowing exchange of oxygen and nutrients necessary for in vitro and in vivo stem cell viability and function. Biocompatibility studies show the device promotes neovascular formation with limited foreign body response in vivo. The device also successfully prevented teratoma escape into the peritoneal cavity of mice. Long-term animal studies demonstrate evidence of engraftment, viability, and function of cells encapsulated in the device after 6 months. Finally, in vivo study confirms that the device was able to effectively immuno-isolate cells from the host immune system.

Published

2017

3. Enhanced Prostate-specific Membrane Antigen Targeting by Precision Control of DNA Scaffolded Nanoparticle Ligand Presentation.

Author

Jana, Deblin, Han, Zhiyuan, Huang, Xiao, Wadhwa, Anju, Raveendran, Athira, Ebeid, Kareem, Meher, Niranjan, Flavell, Robert R., and Desai, Tejal

Published

2024

4. Fabrication of Sealed Nanostraw Microdevices for Oral Drug Delivery

Author

Fox, Cade B, Cao, Yuhong, Nemeth, Cameron L, Chirra, Hariharasudhan D, Chevalier, Rachel W, Xu, Alexander M, Melosh, Nicholas A, and Desai, Tejal A

Subjects

Medical Biotechnology, Biomedical and Clinical Sciences, Engineering, Biomedical Engineering, Biotechnology, Digestive Diseases, Oral and gastrointestinal, Administration, Oral, Drug Delivery Systems, Nanostructures, Pharmaceutical Preparations, microdevices, nanobiotechnology, nanostraws, nanowires, oral drug delivery, Nanoscience & Nanotechnology

Abstract

The oral route is preferred for systemic drug administration and provides direct access to diseased tissue of the gastrointestinal (GI) tract. However, many drugs have poor absorption upon oral administration due to damaging enzymatic and pH conditions, mucus and cellular permeation barriers, and limited time for drug dissolution. To overcome these limitations and enhance oral drug absorption, micron-scale devices with planar, asymmetric geometries, termed microdevices, have been designed to adhere to the lining of the GI tract and release drug at high concentrations directly toward GI epithelium. Here we seal microdevices with nanostraw membranes-porous nanostructured biomolecule delivery substrates-to enhance the properties of these devices. We demonstrate that the nanostraws facilitate facile drug loading and tunable drug release, limit the influx of external molecules into the sealed drug reservoir, and increase the adhesion of devices to epithelial tissue. These findings highlight the potential of nanostraw microdevices to enhance the oral absorption of a wide range of therapeutics by binding to the lining of the GI tract, providing prolonged and proximal drug release, and reducing the exposure of their payload to drug-degrading biomolecules.

Published

2016

5. Polycaprolactone Thin-Film Micro- and Nanoporous Cell-Encapsulation Devices

Author

Nyitray, Crystal E, Chang, Ryan, Faleo, Gaetano, Lance, Kevin D, Bernards, Daniel A, Tang, Qizhi, and Desai, Tejal A

Subjects

Engineering, Biomedical Engineering, Assistive Technology, Transplantation, Bioengineering, Development of treatments and therapeutic interventions, 5.2 Cellular and gene therapies, Animals, Cell Culture Techniques, Cell Survival, Cells, Cultured, Mice, Nanoparticles, Particle Size, Polyesters, Porosity, Surface Properties, cell-encapsulation, polycaprolactone, immunoisolation, nanoporous, microporous, Nanoscience & Nanotechnology

Abstract

Cell-encapsulating devices can play an important role in advancing the types of tissue available for transplantation and further improving transplant success rates. To have an effective device, encapsulated cells must remain viable, respond to external stimulus, and be protected from immune responses, and the device itself must elicit a minimal foreign body response. To address these challenges, we developed a micro- and a nanoporous thin-film cell encapsulation device from polycaprolactone (PCL), a material previously used in FDA-approved biomedical devices. The thin-film device construct allows long-term bioluminescent transfer imaging, which can be used for monitoring cell viability and device tracking. The ability to tune the microporous and nanoporous membrane allows selective protection from immune cell invasion and cytokine-mediated cell death in vitro, all while maintaining typical cell function, as demonstrated by encapsulated cells' insulin production in response to glucose stimulation. To demonstrate the ability to track, visualize, and monitor the viability of cells encapsulated in implanted thin-film devices, we encapsulated and implanted luciferase-positive MIN6 cells in allogeneic mouse models for up to 90 days. Lack of foreign body response in combination with rapid neovascularization around the device shows promise in using this technology for cell encapsulation. These devices can help elucidate the metrics required for cell encapsulation success and direct future immune-isolation therapies.

Published

2015

6. Injectable Polymeric Cytokine-Binding Nanowires Are Effective Tissue-Specific Immunomodulators

Author

Zamecnik, Colin R., primary, Lowe, Margaret M., additional, Patterson, David M., additional, Rosenblum, Michael D., additional, and Desai, Tejal A., additional

Published

2017

7. Shape Effect in the Design of Nanowire-Coated Microparticles as Transepithelial Drug Delivery Devices

Author

Uskoković, Vuk, primary, Lee, Kunwoo, additional, Lee, Phin Peng, additional, Fischer, Kathleen E., additional, and Desai, Tejal A., additional

Published

2012

8. In vitro Immunogenicity of Silicon-Based Micro- and Nanostructured Surfaces

Author

Ainslie, Kristy M., primary, Tao, Sarah L., additional, Popat, Ketul C., additional, and Desai, Tejal A., additional

Published

2008

9. Surfactant-Free, Drug-Quantum-Dot Coloaded Poly(lactide-co-glycolide) Nanoparticles: Towards Multifunctional Nanoparticles

Author

Nehilla, Barrett J., primary, Allen, Philip G., additional, and Desai, Tejal A., additional

Published

2008

10. In vitro Immunogenicity of Silicon-Based Micro- and Nanostructured Surfaces

Author

M. Ainslie, Kristy, A. Desai, Tejal, M. Ainslie, Kristy, L. Tao, Sarah, C. Popat, Ketul, A. Desai, Tejal, L. Tao, Sarah, and C. Popat, Ketul

Abstract

The increasing use of micro- and nanostructured silicon-based devices for in vivotherapeutic or sensing applications highlights the importance of understanding the immunogenicity of these surfaces. Four silicon surfaces (nanoporous, microstructured, nanochanneled, and flat) were studied for their ability to provoke an immune response in human blood derived monocytes. The monocytes were incubated with the surfaces for 48 h and the immunogenicity was evaluated based on the viability, shape factors, and cytokine expression. Free radical oxygen formation was measured at 18 h to elicit a possible mechanism invoking immunogenicity. Although no cytokines were significantly different comparing the response of monocytes on the tissue culture polystyrene surfaces to those on the micropeaked surfaces, on average all cytokines were elevated on the micropeaked surface. The monocytes on the nanoporous surface also displayed an elevated cytokine response, overall, but not to the degree of those on the micropeaked surface. The nanochanneled surface response was similar to that of flat silicon. Overall, the immunogenicity and biocompatibility of flat, nanochanneled, and nanoporous silicon toward human monocytes are approximately equivalent to tissue culture polystyrene.

Published

2008

11. Surfactant-Free, Drug-Quantum-Dot Coloaded Poly(lactide-co-glycolide) Nanoparticles: Towards Multifunctional Nanoparticles

Author

J. Nehilla, Barrett, A. Desai, Tejal, G. Allen, Philip, and A. Desai, Tejal

Abstract

Nanoprecipitation was utilized to synthesize biodegradable and surfactant-free nanoparticles loaded with quantum dots. This protocol also yielded nanoparticles coloaded with both quantum dots and hydrophobic drug (Coenzyme Q10) molecules. Importantly, even though surfactants were not utilized during the nanoprecipitation procedure, these loaded nanoparticles did not aggregate. Dialysis efficiently removed unencapsulated quantum dots from nanoparticle suspensions without altering the physical properties of the quantum-dot-loaded nanoparticles. The resultant purified, quantum-dot-loaded nanoparticles were biocompatible in differentiated PC12 cell cultures, which facilitated their use as nanoparticles in microscopy. In fact, confocal imaging studies showed that purified, quantum-dot-loaded nanoparticles were associated with PC12 cells after one day in vitro. These novel and multifunctional coloaded nanoparticles may prove advantageous in future simultaneous drug delivery and imaging applications.

Published

2008