Your search keyword '"Maxence O. Dellacherie"' showing total 5 results

1. Targeting tumor extracellular matrix activates the tumor-draining lymph nodes

Author

Alexander J, Najibi, Ting-Yu, Shih, David K Y, Zhang, Junzhe, Lou, Miguel C, Sobral, Hua, Wang, Maxence O, Dellacherie, Kwasi, Adu-Berchie, and David J, Mooney

Subjects

Ovalbumin, Antigens, Neoplasm, Melanoma, Experimental, Animals, Humans, Hyaluronoglucosaminidase, Dendritic Cells, Lymph Nodes, Cancer Vaccines, Cryogels, Extracellular Matrix

Abstract

Disruption of the tumor extracellular matrix (ECM) may alter immune cell infiltration into the tumor and antitumor T cell priming in the tumor-draining lymph nodes (tdLNs). Here, we explore how intratumoral enzyme treatment (ET) of B16 melanoma tumors with ECM-depleting enzyme hyaluronidase alters adaptive and innate immune populations, including T cells, DCs, and macrophages, in the tumors and tdLNs. ET increased CD103

Published

2021

2. Biomaterial vaccines capturing pathogen-associated molecular patterns protect against bacterial infections and septic shock

Author

Michael, Super, Edward J, Doherty, Mark J, Cartwright, Benjamin T, Seiler, Fernanda, Langellotto, Nikolaos, Dimitrakakis, Des A, White, Alexander G, Stafford, Mohan, Karkada, Amanda R, Graveline, Caitlin L, Horgan, Kayla R, Lightbown, Frank R, Urena, Chyenne D, Yeager, Sami A, Rifai, Maxence O, Dellacherie, Aileen W, Li, Collin, Leese-Thompson, Hamza, Ijaz, Amanda R, Jiang, Vasanth, Chandrasekhar, Justin M, Scott, Shanda L, Lightbown, Donald E, Ingber, and David J, Mooney

Subjects

Methicillin-Resistant Staphylococcus aureus, Mice, Vaccines, Swine, Pathogen-Associated Molecular Pattern Molecules, Escherichia coli, Animals, Biocompatible Materials, Bacterial Infections, Shock, Septic

Abstract

Most bacterial vaccines work for a subset of bacterial strains or require the modification of the antigen or isolation of the pathogen before vaccine development. Here we report injectable biomaterial vaccines that trigger potent humoral and T-cell responses to bacterial antigens by recruiting, reprogramming and releasing dendritic cells. The vaccines are assembled from regulatorily approved products and consist of a scaffold with absorbed granulocyte-macrophage colony-stimulating factor and CpG-rich oligonucleotides incorporating superparamagnetic microbeads coated with the broad-spectrum opsonin Fc-mannose-binding lectin for the magnetic capture of pathogen-associated molecular patterns from inactivated bacterial-cell-wall lysates. The vaccines protect mice against skin infection with methicillin-resistant Staphylococcus aureus, mice and pigs against septic shock from a lethal Escherichia coli challenge and, when loaded with pathogen-associated molecular patterns isolated from infected animals, uninfected animals against a challenge with different E. coli serotypes. The strong immunogenicity and low incidence of adverse events, a modular manufacturing process, and the use of components compatible with current good manufacturing practice could make this vaccine technology suitable for responding to bacterial pandemics and biothreats.

Published

2020

3. A facile approach to enhance antigen response for personalized cancer vaccination

Author

Aileen Weiwei Li, Young Jin Choi, Soumya Badrinath, Kai W. Wucherpfennig, Maxence O. Dellacherie, Jaeyun Kim, Alexander G. Stafford, James C. Weaver, Amanda R. Graveline, Ting-Yu Shih, David J. Mooney, Miguel C. Sobral, and Omar Abdel-Rahman Ali

Subjects

0301 basic medicine, Drug Compounding, Peptide, macromolecular substances, 02 engineering and technology, Cancer Vaccines, Mice, 03 medical and health sciences, Immune system, Antigen, Antigens, Neoplasm, Cell Line, Tumor, Animals, Humans, Medicine, General Materials Science, Precision Medicine, chemistry.chemical_classification, business.industry, Mechanical Engineering, Immunogenicity, Vaccination, Cancer, General Chemistry, Dendritic cell, 021001 nanoscience & nanotechnology, Condensed Matter Physics, medicine.disease, 3. Good health, 030104 developmental biology, chemistry, Mechanics of Materials, Cell culture, Cancer research, 0210 nano-technology, business

Abstract

Existing strategies to enhance peptide immunogenicity for cancer vaccination generally require direct peptide alteration, which, beyond practical issues, may impact peptide presentation and result in vaccine variability. Here, we report a simple adsorption approach using polyethyleneimine (PEI) in a mesoporous silica microrod (MSR) vaccine to enhance antigen immunogenicity. The MSR–PEI vaccine significantly enhanced host dendritic cell activation and T-cell response over the existing MSR vaccine and bolus vaccine formulations. Impressively, a single injection of the MSR–PEI vaccine using an E7 peptide completely eradicated large, established TC-1 tumours in about 80% of mice and generated immunological memory. When immunized with a pool of B16F10 or CT26 neoantigens, the MSR–PEI vaccine eradicated established lung metastases, controlled tumour growth and synergized with anti-CTLA4 therapy. Our findings from three independent tumour models suggest that the MSR-PEI vaccine approach may serve as a facile and powerful multi-antigen platform to enable robust personalized cancer vaccination. A strategy to enhance antigen immunogenicity is shown using polyethyleneimine adsorbed on mesoporous silica microrod vaccine as a platform for neoantigens, supporting potent humoral immune response and inhibition of tumour growth following vaccination.

Published

2018

4. Covalent Conjugation of Peptide Antigen to Mesoporous Silica Rods to Enhance Cellular Responses

Author

Beverly Y. Lu, Aileen W. Li, David J. Mooney, and Maxence O. Dellacherie

Subjects

0301 basic medicine, Cellular immunity, Ovalbumin, medicine.medical_treatment, Biomedical Engineering, Pharmaceutical Science, Bioengineering, Peptide, Sulfides, 03 medical and health sciences, Antigen, medicine, Animals, Disulfides, Antigens, Cells, Cultured, Pharmacology, chemistry.chemical_classification, Immunity, Cellular, Nanotubes, Tissue Scaffolds, biology, Chemistry, Immunogenicity, Organic Chemistry, Dendritic Cells, Immunotherapy, Mesoporous silica, Silicon Dioxide, In vitro, Mice, Inbred C57BL, 030104 developmental biology, Biophysics, biology.protein, Female, Peptides, Oxidation-Reduction, Porosity, Biotechnology

Abstract

Short peptides are the minimal modality of antigen recognized by cellular immunity and are therefore considered a safe and highly specific source of antigen for vaccination. Nevertheless, successful peptide immunotherapy is limited by the short half-life of peptide antigens in vivo as well as their weak immunogenicity. We recently reported a vaccine strategy based on dendritic cell-recruiting Mesoporous Silica Rod (MSR) scaffolds to enhance T-cell responses against subunit antigen. In this study, we investigated the effect of covalently conjugating peptide antigens to MSRs to increase their retention in the scaffolds. Using both stable thioether and reducible disulfide linkages, peptide conjugation greatly increased peptide loading compared to passive adsorption. In vitro, Bone Marrow derived Dendritic Cells (BMDCs) could present Ovalbumin (OVA)-derived peptides conjugated to MSRs and induce antigen-specific T-cell proliferation. Stable conjugation decreased presentation in vitro while reducible conjugation maintained levels of presentation as high as soluble peptide. Compared to soluble peptide, in vitro, expansion of OT-II T-cells was not affected by adsorption or stable conjugation to MSRs but was enhanced with reversible conjugation to MSRs. Both conjugation schemes increased peptide residence time in MSR scaffolds in vivo compared to standard bolus injections or a simple adsorption method. When MSR scaffolds loaded with GM-CSF and CpG-ODN were injected subcutaneously, recruited dendritic cells could present antigen in situ with the stable conjugation increasing presentation capacity. Overall, this simple conjugation approach could serve as a versatile platform to efficiently incorporate peptide antigens in MSR vaccines and potentiate cellular responses.

Published

2018

5. Hydrogel substrate stress-relaxation regulates the spreading and proliferation of mouse myoblasts

Author

Weiwei Aileen Li, David J. Mooney, Aline Bauer, Maxence O. Dellacherie, Luo Gu, Adam D. Celiz, and Brian J. Kwee

Subjects

0301 basic medicine, Myoblast, Materials science, Alginates, Cell Culture Techniques, Biomedical Engineering, Matrix (biology), Biochemistry, Article, Viscoelasticity, Cell Line, Myoblasts, Biomaterials, Extracellular matrix, Mice, 03 medical and health sciences, Glucuronic Acid, Elastic Modulus, MD Multidisciplinary, Cell Adhesion, Stress relaxation, Extracellular, Animals, Myocyte, Molecular Biology, Elastic modulus, Hexuronic Acids, Alginate, technology, industry, and agriculture, Hydrogels, General Medicine, Anatomy, musculoskeletal system, Hydrogel, 030104 developmental biology, Self-healing hydrogels, Biophysics, Stress, Mechanical, Stress-relaxation, Biotechnology

Abstract

Mechanical properties of the extracellular microenvironment are known to alter cellular behavior, such as spreading, proliferation or differentiation. Previous studies have primarily focused on studying the effect of matrix stiffness on cells using hydrogel substrates that exhibit purely elastic behavior. However, these studies have neglected a key property exhibited by the extracellular matrix (ECM) and various tissues; viscoelasticity and subsequent stress-relaxation. As muscle exhibits viscoelasticity, stress-relaxation could regulate myoblast behavior such as spreading and proliferation, but this has not been previously studied. In order to test the impact of stress relaxation on myoblasts, we created a set of two-dimensional RGD-modified alginate hydrogel substrates with varying initial elastic moduli and rates of relaxation. The spreading of myoblasts cultured on soft stress-relaxing substrates was found to be greater than cells on purely elastic substrates of the same initial elastic modulus. Additionally, the proliferation of myoblasts was greater on hydrogels that exhibited stress-relaxation, as compared to cells on elastic hydrogels of the same modulus. These findings highlight stress-relaxation as an important mechanical property in the design of a biomaterial system for the culture of myoblasts. STATEMENT OF SIGNIFICANCE: This article investigates the effect of matrix stress-relaxation on spreading and proliferation of myoblasts by using tunable elastic and stress-relaxing alginate hydrogels substrates with different initial elastic moduli. Many past studies investigating the effect of mechanical properties on cell fate have neglected the viscoelastic behavior of extracellular matrices and various tissues and used hydrogels exhibiting purely elastic behavior. Muscle tissue is viscoelastic and exhibits stress-relaxation. Therefore, stress-relaxation could regulate myoblast behavior if it were to be incorporated into the design of hydrogel substrates. Altogether, we showed that stress-relaxation impacts myoblasts spreading and proliferation. These findings enable a better understanding of myoblast behavior on viscoelastic substrates and could lead to the design of more suitable substrates for myoblast expansion in vitro.

Published

2017