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1. Transfer learning in a biomaterial fibrosis model identifies in vivo senescence heterogeneity and contributions to vascularization and matrix production across species and diverse pathologies

Author

Cherry, Christopher, Andorko, James I., Krishnan, Kavita, Mejías, Joscelyn C., Nguyen, Helen Hieu, Stivers, Katlin B., Gray-Gaillard, Elise F., Ruta, Anna, Han, Jin, Hamada, Naomi, Hamada, Masakazu, Sturmlechner, Ines, Trewartha, Shawn, Michel, John H., Davenport Huyer, Locke, Wolf, Matthew T., Tam, Ada J., Peña, Alexis N., Keerthivasan, Shilpa, Le Saux, Claude Jordan, Fertig, Elana J., Baker, Darren J., Housseau, Franck, van Deursen, Jan M., Pardoll, Drew M., and Elisseeff, Jennifer H.

Published
2023
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9. Helminth egg derivatives as proregenerative immunotherapies.

Author

Maestas jr., David R., Chung, Liam, Han, Jin, Wang, Xiaokun, Sommerfeld, Sven D., Kelly, Sean H., Moore, Erika, Nguyen, Helen Hieu, Mejías, Joscelyn C., Peña, Alexis N., Zhang, Hong, Hooks, Joshua S. T., Chin, Alexander F., Andorko, James I., Berlinicke, Cynthia A., Krishnan, Kavita, Younghwan Choi, Anderson, Amy E., Mahatme, Ronak, and Mejia, Christopher

Subjects
T helper cells, REGULATORY T cells, SCHISTOSOMA mansoni, CORNEA injuries, REGENERATION (Biology)
Abstract

The immune system is increasingly recognized as an important regulator of tissue repair. We developed a regenerative immunotherapy from the helminth Schistosoma mansoni soluble egg antigen (SEA) to stimulate production of interleukin (IL)-4 and other type 2-associated cytokines without negative infection-related sequelae. The regenerative SEA (rSEA) applied to a murine muscle injury induced accumulation of IL-4-expressing T helper cells, eosinophils, and regulatory T cells and decreased expression of IL-17A in gamma delta (Yκ) T cells, resulting in improved repair and decreased fibrosis. Encapsulation and controlled release of rSEA in a hydrogel further enhanced type 2 immunity and larger volumes of tissue repair. The broad regenerative capacity of rSEA was validated in articular joint and corneal injury models. These results introduce a regenerative immunotherapy approach using natural helminth derivatives. [ABSTRACT FROM AUTHOR]

Published
2023
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12. Interleukin 17 and senescent cells regulate the foreign body response to synthetic material implants in mice and humans.

Author

Chung, Liam, Maestas, David R., Lebid, Andriana, Mageau, Ashlie, Rosson, Gedge D., Wu, Xinqun, Wolf, Matthew T., Tam, Ada J., Vanderzee, Isabel, Wang, Xiaokun, Andorko, James I., Zhang, Hong, Narain, Radhika, Sadtler, Kaitlyn, Fan, Hongni, Čiháková, Daniela, Le Saux, Claude Jourdan, Housseau, Franck, Pardoll, Drew M., and Elisseeff, Jennifer H.

Subjects
FOREIGN bodies, T cells, INTERLEUKIN-17, BREAST implants, INNATE lymphoid cells, STROMAL cells, SCARS, MYOFIBROBLASTS
Abstract

Elucidating the foreign body response: Synthetic materials are the building blocks for medical devices and implants but can induce a foreign body response after implantation, resulting in fibrous scar tissue encompassing the implant. Here, Chung et al. define the role of interleukin 17 (IL17) and cellular senescence in driving the foreign body response. The fibrous capsule from excised breast implants contained IL17-producing T cells and senescent stromal cells. These findings were further validated in a murine model, and the authors found that blocking the IL17 pathway or eliminating senescent cells mitigated local fibrosis around the implant. This study presents new potential therapeutic targets to reduce fibrosis associated with the foreign body response. Medical devices and implants made of synthetic materials can induce an immune-mediated process when implanted in the body called the foreign body response, which results in formation of a fibrous capsule around the implant. To explore the immune and stromal connections underpinning the foreign body response, we analyzed fibrotic capsules surrounding surgically excised human breast implants from 12 individuals. We found increased numbers of interleukin 17 (IL17)–producing γδ+ T cells and CD4+ T helper 17 (TH17) cells as well as senescent stromal cells in the fibrotic capsules. Further analysis in a murine model demonstrated an early innate IL17 response to implanted synthetic material (polycaprolactone) particles that was mediated by innate lymphoid cells and γδ+ T cells. This was followed by a chronic adaptive CD4+ TH17 cell response that was antigen dependent. Synthetic materials with varying chemical and physical properties implanted either in injured muscle or subcutaneously induced similar IL17 responses in mice. Mice deficient in IL17 signaling established that IL17 was required for the fibrotic response to implanted synthetic materials and the development of p16INK4a senescent cells. IL6 produced by senescent cells was sufficient for the induction of IL17 expression in T cells. Treatment with a senolytic agent (navitoclax) that killed senescent cells reduced IL17 expression and fibrosis in the mouse implant model. Discovery of a feed-forward loop between the TH17 immune response and the senescence response to implanted synthetic materials introduces new targets for therapeutic intervention in the foreign body response. [ABSTRACT FROM AUTHOR]

Published
2020
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13. Engineering Immunological Tolerance Using Quantum Dots to Tune the Density of Self-Antigen Display.

Author

Hess, Krystina L., Oh, Eunkeu, Tostanoski, Lisa H., Andorko, James I., Susumu, Kimihiro, Deschamps, Jeffrey R., Medintz, Igor L., and Jewell, Christopher M.

Subjects
AUTOIMMUNE disease treatment, IMMUNOLOGICAL tolerance, QUANTUM dots, AUTOANTIGENS, MULTIPLE sclerosis
Abstract

Treatments for autoimmunity-diseases where the immune system mistakenly attacks self-molecules-are not curative and leave patients immunocompromised. New studies aimed at more specific treatments reveal that development of inflammation or tolerance is influenced by the form in which self-antigens are presented. Using a mouse model of multiple sclerosis (MS), it is shown for the first time that quantum dots (QDs) can be used to generate immunological tolerance by controlling the density of self-antigen on QDs. These assemblies display dense arrangements of myelin self-peptide associated with disease in MS, are uniform in size (<20 nm), and allow direct visualization in immune tissues. Peptide-QDs rapidly concentrate in draining lymph nodes, colocalizing with macrophages expressing scavenger receptors involved in tolerance. Treatment with peptide-QDs reduces disease incidence tenfold. Strikingly, the degree of tolerance-and the underlying expansion of regulatory T cells-correlates with the density of myelin molecules presented on QDs. A key discovery is that higher numbers of tolerogenic particles displaying lower levels of self-peptide are more effective for inducing tolerance than fewer particles each displaying higher densities of peptide. QDs conjugated with self-antigens can serve as a new platform to induce tolerance, while visualizing QD therapeutics in tolerogenic tissue domains. [ABSTRACT FROM AUTHOR]

Published
2017
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14. Designing biomaterials with immunomodulatory properties for tissue engineering and regenerative medicine.

Author

Andorko, James I. and Jewell, Christopher M.

Subjects
*IMMUNOTHERAPY, *VACCINES, *DENDRITIC cells, *TISSUE engineering, *INFLAMMATION
Abstract

Recent research in the vaccine and immunotherapy fields has revealed that biomaterials have the ability to activate immune pathways, even in the absence of other immune-stimulating signals. Intriguingly, new studies reveal these responses are influenced by the physicochemical properties of the material. Nearly all of this work has been done in the vaccine and immunotherapy fields, but there is tremendous opportunity to apply this same knowledge to tissue engineering and regenerative medicine. This review discusses recent findings that reveal how material properties-size, shape, chemical functionality-impact immune response, and links these changes to emerging opportunities in tissue engineering and regenerative medicine. We begin by discussing what has been learned from studies conducted in the contexts of vaccines and immunotherapies. Next, research is highlighted that elucidates the properties of materials that polarize innate immune cells, including macrophages and dendritic cells, toward either inflammatory or wound healing phenotypes. We also discuss recent studies demonstrating that scaffolds used in tissue engineering applications can influence cells of the adaptive immune system-B and T cell lymphocytes-to promote regenerative tissue microenvironments. Through greater study of the intrinsic immunogenic features of implantable materials and scaffolds, new translational opportunities will arise to better control tissue engineering and regenerative medicine applications. [ABSTRACT FROM AUTHOR]

Published
2017
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15. Impact of molecular weight on the intrinsic immunogenic activity of poly(beta amino esters).

Author

Andorko, James I., Pineault, Kevin G., and Jewell, Christopher M.

Abstract

Polymeric carriers are ubiquitously studied in vaccine and drug delivery to control the encapsulation, kinetics, and targeting of cargo. Recent research reveals many polymers can cause immunostimulatory and inflammatory responses, even in the absence of other immune signals. However, the extent to which this intrinsic immunogenicity evolves during degradation is understudied. Here we synthesized a small library of poly(beta amino esters) (PBAEs) that exhibit different starting molecular weights (MWs), but with similar and rapid degradation rates. Primary dendritic cells (DCs) treated with free PBAEs, either intact or degraded to form low MW fragments, were not activated. In contrast particles formed from PBAEs at different extents of degradation caused differential expression of classical DC activation markers (for example, CD40, CD80, CD86, MHCII), as well as antigen presentation. During degradation, activation levels changed with changing physicochemical properties (for example, MW, concentration, size, charge). Of note, irrespective of starting MW, immunogenicity peaked when the MW of degrading PBAEs decreased to a range of ∼1500-3000 Da. These findings could help inform design of future carriers that exploit the dynamic interactions with the immune system as materials degrade, leading to carriers that deliver cargo but also help direct the immune responses to vaccine or immunotherapy cargo. © 2017 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 105A: 1219-1229, 2017. [ABSTRACT FROM AUTHOR]

Published
2017
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16. Impact of dose, route, and composition on the immunogenicity of immune polyelectrolyte multilayers delivered on gold templates.

Author

Zhang, Peipei, Andorko, James I., and Jewell, Christopher M.

Abstract

ABSTRACT Biomaterial vaccines offer new capabilities that can be exploited for both infectious disease and cancer. We recently developed a novel vaccine platform based on self-assembly of immune signals into immune polyelectrolyte multilayers (iPEMs). These iPEM vaccines are electrostatically assembled from peptide antigens and nucleic acid-based toll-like receptor agonists (TLRas) that serve as molecular adjuvants. Gold nanoparticles (AuNPs) coated with iPEMs stimulate effector cytokine secretion in vitro and expand antigen-specific T cells in mice. Here we investigated how the dose, injection route, and choice of molecular adjuvant impacts the ability of iPEMs to generate T cell immunity and anti-tumor response in mice. Three injection routes-intradermal, subcutaneous, and intramuscular-and three iPEM dosing levels were employed. Intradermal injection induced the most potent antigen-specific T cell responses and, for all routes, the level of response was dose-dependent. We further discovered that these vaccines generate durable memory, indicated by potent, antigen-specific CD8+ T cell recall responses in mice challenged with vaccine 49 days after a prime-boost immunization regimen. In a common exogenous antigen melanoma model, iPEM vaccines slowed or stopped tumor growth more effectively than equivalent ad-mixed formulations. Further, iPEMs containing CpG-a TLR9a-were more potent compared with iPEMs containing polyIC, a TLR3a. These findings demonstrate the ability of iPEMs to enhance response to several different classes of vaccine cargos, supporting iPEMs as a simple vaccine platform that mimics attractive features of other nanoparticles using immune signals that can be self-assembled or coated on substrates. Biotechnol. Bioeng. 2017;114: 423-431. © 2016 Wiley Periodicals, Inc. [ABSTRACT FROM AUTHOR]

Published
2017
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17. Reprogramming the Local Lymph Node Microenvironment Promotes Tolerance that Is Systemic and Antigen Specific.

Author

Tostanoski, Lisa H., Chiu, Yu-Chieh, Gammon, Joshua M., Simon, Thomas, Andorko, James I., Bromberg, Jonathan S., and Jewell, Christopher M.

Abstract

Summary Many experimental therapies for autoimmune diseases, such as multiple sclerosis (MS), aim to bias T cells toward tolerogenic phenotypes without broad suppression. However, the link between local signal integration in lymph nodes (LNs) and the specificity of systemic tolerance is not well understood. We used intra-LN injection of polymer particles to study tolerance as a function of signals in the LN microenvironment. In a mouse MS model, intra-LN introduction of encapsulated myelin self-antigen and a regulatory signal (rapamycin) permanently reversed paralysis after one treatment during peak disease. Therapeutic effects were myelin specific, required antigen encapsulation, and were less potent without rapamycin. This efficacy was accompanied by local LN reorganization, reduced inflammation, systemic expansion of regulatory T cells, and reduced T cell infiltration to the CNS. Our findings suggest that local control over signaling in distinct LNs can promote cell types and functions that drive tolerance that is systemic but antigen specific. [ABSTRACT FROM AUTHOR]

Published
2016
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18. Lipid tethering of breast tumor cells enables real-time imaging of free-floating cell dynamics and drug response

Author

Chakrabarti, Kristi R., Andorko, James I., Whipple, Rebecca A., Zhang, Peipei, Sooklal, Elisabeth L., Martin, Stuart S., and Jewell, Christopher M.

Subjects
breast cancer, polyelectrolyte multilayers, microfluidics, microtentacles, circulating tumor cells, 3. Good health
Abstract

Funding for Open Access provided by the UMD Libraries Open Access Publishing Fund., Free-floating tumor cells located in the blood of cancer patients, known as circulating tumor cells (CTCs), have become key targets for studying metastasis. However, effective strategies to study the free-floating behavior of tumor cells in vitro have been a major barrier limiting the understanding of the functional properties of CTCs. Upon extracellular-matrix (ECM) detachment, breast tumor cells form tubulin-based protrusions known as microtentacles (McTNs) that play a role in the aggregation and re-attachment of tumor cells to increase their metastatic efficiency. In this study, we have designed a strategy to spatially immobilize ECM-detached tumor cells while maintaining their free-floating character. We use polyelectrolyte multilayers deposited on microfluidic substrates to prevent tumor cell adhesion and the addition of lipid moieties to tether tumor cells to these surfaces through interactions with the cell membranes. This coating remains optically clear, allowing capture of high-resolution images and videos of McTNs on viable free-floating cells. In addition, we show that tethering allows for the real-time analysis of McTN dynamics on individual tumor cells and in response to tubulin-targeting drugs. The ability to image detached tumor cells can vastly enhance our understanding of CTCs under conditions that better recapitulate the microenvironments they encounter during metastasis.

20. Immunotherapy: Engineering Immunological Tolerance Using Quantum Dots to Tune the Density of Self-Antigen Display (Adv. Funct. Mater. 22/2017).

Author

Hess, Krystina L., Oh, Eunkeu, Tostanoski, Lisa H., Andorko, James I., Susumu, Kimihiro, Deschamps, Jeffrey R., Medintz, Igor L., and Jewell, Christopher M.

Subjects
IMMUNOTHERAPY, QUANTUM dots, AUTOANTIGENS
Abstract

In article number 1700290, Christopher M. Jewell and co‐workers use quantum dots (yellow) to track and control the display density of self‐molecules mistakenly attacked during autoimmune diseases. This precise display changes self‐molecule processing by antigen‐presenting cells (purple), reprogramming the disease‐driving inflammatory T cells (red) to become regulatory T cells (developing white region on cell) that control disease and eliminate paralysis. [ABSTRACT FROM AUTHOR]

Published
2017
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21. Type 2 immunity induced by bladder extracellular matrix enhances corneal wound healing.

Author

Xiaokun Wang, Liam Chung, Hooks, Joshua, Maestas Jr., David R., Lebid, Andriana, Andorko, James I., Luai Huleihel, Chin, Alexander F., Wolf, Matthew, Remlinger, Nathaniel T., Stepp, Mary Ann, Housseau, Franck, and Elisseeff, Jennifer H.

Subjects
*EXTRACELLULAR matrix, *WOUND healing, *HYPERTROPHIC scars, *CORNEA injuries, *MYOFIBROBLASTS, *CYTOLOGY, *CELL anatomy
Published
2021
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22. Type 2 immunity induced by bladder extracellular matrix enhances corneal wound healing.

Author

Wang X, Chung L, Hooks J, Maestas DR Jr, Lebid A, Andorko JI, Huleihel L, Chin AF, Wolf M, Remlinger NT, Stepp MA, Housseau F, and Elisseeff JH

Subjects
Animals, Cornea pathology, Extracellular Matrix metabolism, Mice, Swine, Wound Healing physiology, Corneal Injuries pathology, Urinary Bladder metabolism
Abstract

The avascular nature of cornea tissue limits its regenerative potential, which may lead to incomplete healing and formation of scars when damaged. Here, we applied micro- and ultrafine porcine urinary bladder matrix (UBM) particulate to promote type 2 immune responses in cornea wounds. Results demonstrated that UBM particulate substantially reduced corneal haze formation as compared to the saline-treated group. Flow cytometry and gene expression analysis showed that UBM particulate suppressed the differentiation of corneal stromal cells into α-smooth muscle actin-positive (αSMA + ) myofibroblasts. UBM treatments up-regulated interleukin-4 (IL-4) produced primarily by eosinophils in the wounded corneas and CD4 + T cells in draining lymph nodes, suggesting a cross-talk between local and peripheral immunity. Gata1 -/- mice lacking eosinophils did not respond to UBM treatment and had impaired wound healing. In summary, stimulating type 2 immune responses in the wounded cornea can promote proregenerative environments that lead to improved wound healing for vision restoration., (Copyright © 2021 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution NonCommercial License 4.0 (CC BY-NC).)

Published
2021
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23. Extracting microtentacle dynamics of tumor cells in a non-adherent environment.

Author

Ory EC, Chen D, Chakrabarti KR, Zhang P, Andorko JI, Jewell CM, Losert W, and Martin SS

Abstract

During metastasis, tumor cells dynamically change their cytoskeleton to traverse through a variety of non-adherent microenvironments, including the vasculature or lymphatics. Due to the challenges of imaging drift in non-adhered tumor cells, the dynamic cytoskeletal phenotypes are poorly understood. We present a new approach to analyze the dynamic cytoskeletal phenotypes of non-adhered cells that support microtentacles (McTNs), which are cell surface projections implicated in metastatic reattachment. Combining a recently-developed cell tethering method with a novel image analysis framework allowed McTN attribute extraction. Full cell outlines, number of McTNs, and distance of McTN tips from the cell body boundary were calculated by integrating a rotating anisotropic filtering method for identifying thin features with retinal segmentation and active contour algorithms. Tethered cells behave like free-floating cells; however tethering reduces cell drift and improves the accuracy of McTN measurements. Tethering cells does not significantly alter McTN number, but rather allows better visualization of existing McTNs. In drug treatment experiments, stabilizing tubulin with paclitaxel significantly increases McTN length, while destabilizing tubulin with colchicine significantly decreases McTN length. Finally, we quantify McTN dynamics by computing the time delay autocorrelations of 2 composite phenotype metrics (cumulative McTN tip distance, cell perimeter:cell body ratio). Our automated analysis demonstrates that treatment with paclitaxel increases total McTN amount and colchicine reduces total McTN amount, while paclitaxel also reduces McTN dynamics. This analysis method enables rapid quantitative measurement of tumor cell drug responses within non-adherent microenvironments, using the small numbers of tumor cells that would be available from patient samples., Competing Interests: CONFLICTS OF INTEREST AND FUNDING This work was supported in part by the Kahlert Foundation, R01-CA124624 and R01-CA154624, an Era of Hope Scholar Award (BC100675) from the Department of Defense, University of Maryland Tier II program, and NSF CAREER Award #1351688. WL was supported by NIH grant R01GM085574. C.M.J. is a Young Investigator of the Damon Runyon Foundation, Alliance for Cancer Gene Therapy, and Melanoma Research Alliance. K.R.C is supported by F30-CA196075 and 5T32CA154274 from NCI. J.I.A. is a trainee on NIH Grant # T32 AI089621 and a Graduate Fellow supported by the American Association of Pharmaceutical Scientists Foundation. The University of Maryland has copyrighted the McTN analysis software on which E.O., W.L. and S.S.M. are listed as authors. The University of Maryland has patents pending on the microfluidic cell tethering technology on which K.R.C, P.Z., J.I.A., C.M.J. and S.S.M. are listed as inventors.

Published
2017
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24. Design of Polyelectrolyte Multilayers to Promote Immunological Tolerance.

Author

Tostanoski LH, Chiu YC, Andorko JI, Guo M, Zeng X, Zhang P, Royal W 3rd, and Jewell CM

Abstract

Recent studies demonstrate that excess signaling through inflammatory pathways (e.g., toll-like receptors, TLRs) contributes to the pathogenesis of human autoimmune diseases, including lupus, diabetes, and multiple sclerosis (MS). We hypothesized that codelivery of a regulatory ligand of TLR9, GpG oligonucleotide, along with myelin-the "self" molecule attacked in MS-might restrain the pro-inflammatory signaling typically present during myelin presentation, redirecting T cell differentiation away from inflammatory populations and toward tolerogenic phenotypes such as regulatory T cells. Here we show that myelin peptide and GpG can be used as modular building blocks for co-assembly into immune polyelectrolyte multilayers (iPEMs). These nanostructured capsules mimic attractive features of biomaterials, including tunable cargo loading and codelivery, but eliminate all carriers and synthetic polymers, components that often exhibit intrinsic inflammatory properties that could exacerbate autoimmune disease. In vitro, iPEMs assembled from myelin and GpG oligonucleotide, but not myelin and a control oligonucleotide, restrain TLR9 signaling, reduce dendritic cell activation, and polarize myelin-specific T cells toward tolerogenic phenotype and function. In mice, iPEMs blunt myelin-triggered inflammatory responses, expand regulatory T cells, and eliminate disease in a common model of MS. Finally, in samples from human MS patients, iPEMs bias myelin-triggered immune cell function toward tolerance. This work represents a unique opportunity to use PEMs to regulate immune function and promote tolerance, supporting iPEMs as a carrier-free platform to alter TLR function to reduce inflammation and combat autoimmunity.

Published
2016
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25. Assembly and Immunological Processing of Polyelectrolyte Multilayers Composed of Antigens and Adjuvants.

Author

Chiu YC, Gammon JM, Andorko JI, Tostanoski LH, and Jewell CM

Subjects
Adjuvants, Immunologic, Animals, Antigens, Dendritic Cells, Mice, Vaccines, Polyelectrolytes chemistry
Abstract

While biomaterials provide a platform to control the delivery of vaccines, the recently discovered intrinsic inflammatory characteristics of many polymeric carriers can also complicate rational design because the carrier itself can alter the response to other vaccine components. To address this challenge, we recently developed immune-polyelectrolyte multilayer (iPEMs) capsules electrostatically assembled entirely from peptide antigen and molecular adjuvants. Here, we use iPEMs built from SIINFEKL model antigen and polyIC, a stimulatory toll-like receptor agonist, to investigate the impact of pH on iPEM assembly, the processing and interactions of each iPEM component with primary immune cells, and the role of these interactions during antigen-specific T cell responses in coculture and mice. We discovered that iPEM assembly is pH dependent with respect to both the antigen and adjuvant component. Controlling the pH also allows tuning of the relative loading of SIINFEKL and polyIC in iPEM capsules. During in vitro studies with primary dendritic cells (DCs), iPEM capsules ensure that greater than 95% of cells containing at least one signal (i.e., antigen, adjuvant) also contained the other signal. This codelivery leads to DC maturation and SIINFEKL presentation via the MHC-I antigen presentation pathway, resulting in antigen-specific T cell proliferation and pro-inflammatory cytokine secretion. In mice, iPEM capsules potently expand antigen-specific T cells compared with equivalent admixed formulations. Of note, these enhancements become more pronounced with successive booster injections, suggesting that iPEMs functionally improve memory recall response. Together our results reveal some of the features that can be tuned to modulate the properties of iPEM capsules, and how these modular vaccine structures can be used to enhance interactions with immune cells in vitro and in mice.

Published
2016
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26. Lipid tethering of breast tumor cells enables real-time imaging of free-floating cell dynamics and drug response.

Author

Chakrabarti KR, Andorko JI, Whipple RA, Zhang P, Sooklal EL, Martin SS, and Jewell CM

Subjects
Antineoplastic Agents pharmacology, Cell Line, Tumor, Cell Surface Extensions pathology, Extracellular Matrix metabolism, Female, Humans, Lipid Metabolism, Lipids, MCF-7 Cells, Neoplasm Metastasis pathology, Tumor Microenvironment physiology, Breast Neoplasms pathology, Cell Adhesion physiology, Cell Aggregation physiology, Diagnostic Imaging methods, Neoplastic Cells, Circulating pathology
Abstract

Free-floating tumor cells located in the blood of cancer patients, known as circulating tumor cells (CTCs), have become key targets for studying metastasis. However, effective strategies to study the free-floating behavior of tumor cells in vitro have been a major barrier limiting the understanding of the functional properties of CTCs. Upon extracellular-matrix (ECM) detachment, breast tumor cells form tubulin-based protrusions known as microtentacles (McTNs) that play a role in the aggregation and re-attachment of tumor cells to increase their metastatic efficiency. In this study, we have designed a strategy to spatially immobilize ECM-detached tumor cells while maintaining their free-floating character. We use polyelectrolyte multilayers deposited on microfluidic substrates to prevent tumor cell adhesion and the addition of lipid moieties to tether tumor cells to these surfaces through interactions with the cell membranes. This coating remains optically clear, allowing capture of high-resolution images and videos of McTNs on viable free-floating cells. In addition, we show that tethering allows for the real-time analysis of McTN dynamics on individual tumor cells and in response to tubulin-targeting drugs. The ability to image detached tumor cells can vastly enhance our understanding of CTCs under conditions that better recapitulate the microenvironments they encounter during metastasis.

Published
2016
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27. Modular Vaccine Design Using Carrier-Free Capsules Assembled from Polyionic Immune Signals.

Author

Chiu YC, Gammon JM, Andorko JI, Tostanoski LH, and Jewell CM

Abstract

New vaccine adjuvants that direct immune cells toward specific fates could support more potent and selective options for diseases spanning infection to cancer. However, the empirical nature of vaccines and the complexity of many formulations has hindered design of well-defined and easily characterized vaccines. We hypothesized that nanostructured capsules assembled entirely from polyionic immune signals might support a platform for simple, modular vaccines. These immune-polyelectrolyte (iPEM) capsules offer a high signal density, selectively expand T cells in mice, and drive functional responses during tumor challenge. iPEMs incorporating clinically relevant antigens could improve vaccine definition and support more programmable control over immunity.

Published
2015
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28. Intra-lymph node injection of biodegradable polymer particles.

Author

Andorko JI, Tostanoski LH, Solano E, Mukhamedova M, and Jewell CM

Subjects
Animals, Biocompatible Materials chemistry, Fatty Acids, Monounsaturated administration & dosage, Fatty Acids, Monounsaturated chemistry, Mice, Particle Size, Phosphatidylcholines administration & dosage, Phosphatidylcholines chemistry, Phosphatidylethanolamines administration & dosage, Phosphatidylethanolamines chemistry, Polyethylene Glycols administration & dosage, Polyethylene Glycols chemistry, Quaternary Ammonium Compounds administration & dosage, Quaternary Ammonium Compounds chemistry, Biocompatible Materials administration & dosage, Drug Delivery Systems methods, Lymph Nodes
Abstract

Generation of adaptive immune response relies on efficient drainage or trafficking of antigen to lymph nodes for processing and presentation of these foreign molecules to T and B lymphocytes. Lymph nodes have thus become critical targets for new vaccines and immunotherapies. A recent strategy for targeting these tissues is direct lymph node injection of soluble vaccine components, and clinical trials involving this technique have been promising. Several biomaterial strategies have also been investigated to improve lymph node targeting, for example, tuning particle size for optimal drainage of biomaterial vaccine particles. In this paper we present a new method that combines direct lymph node injection with biodegradable polymer particles that can be laden with antigen, adjuvant, or other vaccine components. In this method polymeric microparticles or nanoparticles are synthesized by a modified double emulsion protocol incorporating lipid stabilizers. Particle properties (e.g. size, cargo loading) are confirmed by laser diffraction and fluorescent microscopy, respectively. Mouse lymph nodes are then identified by peripheral injection of a nontoxic tracer dye that allows visualization of the target injection site and subsequent deposition of polymer particles in lymph nodes. This technique allows direct control over the doses and combinations of biomaterials and vaccine components delivered to lymph nodes and could be harnessed in the development of new biomaterial-based vaccines.

Published
2014
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