Joel A. Cohen

Acetalated dextran is a chemically and biologically tunable material for particulate immunotherapy

Materials that combine facile synthesis, simple tuning of degradation rate, processability, and biocompatibility are in high demand for use in biomedical applications. We report on acetalated dextran, a biocompatible material that can be formed into microparticles with degradation rates that are tunable over 2 orders of magnitude depending on the degree and type of acetal modification. Varying the degradation rate produces particles that perform better than poly(lactic-co-glycolic acid) and iron oxide, two commonly studied materials used for particulate immunotherapy, in major histocompatibility complex class I (MHC I) and MHC II presentation assays. Modulating the material properties leads to antigen presentation on MHC I via pathways that are dependent or independent of the transporter associated with antigen processing. To the best of our knowledge, this is the only example of a material that can be tuned to operate on different immunological pathways while maximizing immunological presentation.

Acid-Degradable Cationic Dextran Particles for the Delivery of siRNA Therapeutics

We report a new acid-sensitive, biocompatible, and biodegradable microparticulate delivery system, spermine modified acetalated-dextran (Spermine-Ac-DEX), which can be used to efficiently encapsulate siRNA. These particles demonstrated efficient gene knockdown in HeLa-luc cells with minimal toxicity. This knockdown was comparable to that obtained using Lipofectamine, a commercially available transfection reagent generally limited to in vitro use due to its high toxicity.

Two-photon degradable supramolecular assemblies of linear-dendritic copolymers

Micelles of dendritic-linear copolymers have been developed to release a payload after infrared stimulus.

Acetal-modified dextran microparticles with controlled degradation kinetics and surface functionality for gene delivery in phagocytic and non-phagocytic cells.

Controlled intracellular delivery of genetic material for vaccine or other therapeutic applications in vivo remains a major challenge for non-viral delivery systems.[1,2] As an alternative to cationic polymers and lipids commonly used to form nano-scale complexes for in vitro plasmid transfection,[3–6] microparticles made from biodegradable polymers such as poly(lactide-co-glycolide) (PLGA) and acid-sensitive poly(ortho esters) (POEs) and hydrogels have been pursued as in vivo plasmid DNA carriers.[6–9] Due to their size (typically 1–10 μm), these particles passively target phagocytic antigen presenting cells (APCs) of the immune system for DNA vaccine applications.[8] In addition, these particles may alleviate the shortcomings of cationic polymers and lipids with regard to in vivo targeting, toxicity, and stability.[3] Despite their promise, microparticulate delivery systems explored to date often suffer from uncontrolled initial burst release of upwards of 50% of the encapsulated plasmid, independent of any built-in triggered-release mechanism, making it difficult to achieve rapid yet controlled release in response to a specific stimulus.[10] Furthermore, there have been few reports to date of attempts to extend the application of these systems to target non-phagocytic cells, which are present in much greater quantity throughout the body. Herein we report a tunable and modular microparticle system for plasmid delivery that, we hypothesized, would overcome these problems and simultaneously allow the systematic study of the dependence of transfection efficiency on various formulation parameters including degradation kinetics, use of cationic blend polymers, and surface functionalization for the transfection of non-phagocytic cells.

T-Cell Activation by Antigen-Loaded pH-Sensitive Hydrogel Particles in Vivo: The Effect of Particle Size

Polymeric carriers designed to encapsulate protein antigens have great potential for improving the efficacy of vaccines and immunotherapeutics for diseases such as cancer. We recently developed a carrier system based on polyacrylamide hydrogel microparticles cross-linked with acid-labile moieties. After being phagocytosed by antigen-presenting cells, the protein encapsulated within the carrier is released and processed for subsequent presentation of antigenic epitopes. To understand the impact of particle size on the activation of T-cells following uptake by antigen-presenting cells, particles with mean diameters of 3.5 microm and 35 nm encapsulating a model protein antigen were synthesized by emulsion and microemulsion based polymerization techniques, respectively. In vivo tests demonstrated that both sizes of particles were effective at stimulating the proliferation of T-cells and were capable of generating an antigen-specific cytotoxic T-cell response when coadministered with immunostimulatory DNA. Contrary to previous reports in the literature, our results suggest that there is no significant difference in the magnitude of T-cell activation for the two sizes of particles used in these experiments. This disparity in findings may be related to fundamental differences in material properties of the carriers used in these studies, such as the hydrophilicity of the polyacrylamide particles described here versus the hydrophobic nature of carriers investigated by other groups.

Mannosylated dextran nanoparticles: a pH-sensitive system engineered for immunomodulation through mannose targeting.

Biotherapeutic delivery is a rapidly growing field in need of new materials that are easy to modify, are biocompatible, and provide for triggered release of their encapsulated cargo. Herein, we report on a particulate system made of a polysaccharide-based pH-sensitive material that can be efficiently modified to display mannose-based ligands of cell-surface receptors. These ligands are beneficial for antigen delivery, as they enhance internalization and activation of APCs, and are thus capable of modulating immune responses. When compared to unmodified particles or particles modified with a nonspecific sugar residue used in the delivery of antigens to dendritic cells (DCs), the mannosylated particles exhibited enhanced antigen presentation in the context of major histocompatibility complex (MHC) class I molecules. This represents the first demonstration of a mannosylated particulate system that enables enhanced MHC I antigen presentation by DCs in vitro. Our readily functionalized pH-sensitive material may also open new avenues in the development of optimally modulated vaccine delivery systems.

Chemoselective ligation in the functionalization of polysaccharide-based particles.

Despite the promise of precisely targeted or otherwise functionalized polymeric particulate drug delivery vehicles, typical biocompatible particles are generally not amenable to facile and selective surface modification. Herein, we report the development of a simple, mild, and chemoselective strategy for the conjugation of biologically active molecules to the surface of dextran-based microparticles. Alkoxyamine-bearing reagents were used to form stable oxime conjugates with latent aldehyde functionality present in reducing carbohydrate chain ends. We demonstrate the functionalization of dextran-based microparticles with a fluorophore as well as a cell-penetrating peptide sequence, which facilitated the delivery of cargo to nonphagocytic cells leading to a 60-fold increase in the expression of a reporter gene when plasmid DNA-loaded particles were used.

Impact of hydrogel nanoparticle size and functionalization on in vivo behavior for lung imaging and therapeutics.

Polymer chemistry offers the possibility of synthesizing multifunctional nanoparticles which incorporate moieties that enhance diagnostic and therapeutic targeting of cargo delivery to the lung. However, since rules for predicting particle behavior following modification are not well-defined, it is essential that probes for tracking fate in vivo are also included. Accordingly, we designed polyacrylamide-based hydrogel particles of differing sizes, functionalized with a nona-arginine cell-penetrating peptide (Arg(9)), and labeled with imaging components to assess lung retention and cellular uptake after intratracheal administration. Radiolabeled microparticles (1-5 microm diameter) and nanoparticles (20-40 nm diameter) without and with Arg(9) showed diffuse airspace distribution by positron emission tomography imaging. Biodistribution studies revealed that particle clearance and extrapulmonary distribution was, in part, size dependent. Microparticles were rapidly cleared by mucociliary routes but, unexpectedly, also through the circulation. In contrast, nanoparticles had prolonged lung retention enhanced by Arg(9) and were significantly restricted to the lung. For all particle types, uptake was predominant in alveolar macrophages and, to a lesser extent, lung epithelial cells. In general, particles did not induce local inflammatory responses, with the exception of microparticles bearing Arg(9). Whereas microparticles may be advantageous for short-term applications, nanosized particles constitute an efficient high-retention and non-inflammatory vehicle for the delivery of diagnostic imaging agents and therapeutics to lung airspaces and alveolar macrophages that can be enhanced by Arg(9). Importantly, our results show that minor particle modifications may significantly impact in vivo behavior within the complex environments of the lung, underscoring the need for animal modeling.

Enhanced Cell Penetration of Acid-Degradable Particles Functionalized with Cell-Penetrating Peptides

Biopharmaceuticals, such as proteins and DNA, have demonstrated their potential to prevent and cure diseases. The success of such therapeutic agents hinges upon their ability to cross complex barriers in the body and reach their target intact. In order to reap the full benefits of these therapeutic agents, a delivery vehicle capable of delivering cargo to all cell types, both phagocytic and non-phagocytic, is needed. This article presents the synthesis and evaluation of a microparticle delivery vehicle capable of cell penetration and sub-cellular triggered release of an encapsulated payload. pH-sensitive polyacrylamide particles functionalized with a polyarginine cell-penetrating peptide (CPP) were synthesized. The incorporation of a CPP into the microparticles led to efficient uptake by non-phagocytic cells in culture. In addition, the CPP-modified particles showed no cytotoxic effects at concentrations used in this study. The results suggest that these particles may provide a vehicle for the successful delivery of therapeutic agents to various cell types.