PEGylated PLGA nanoparticles for the improved delivery of doxorubicin.

We hypothesize that the efficacy of doxorubicin (DOX) can be maximized and dose-limiting cardiotoxicity minimized by controlled release from PEGylated nanoparticles. To test this hypothesis, a unique surface modification technique was used to create PEGylated poly(lactic-co-glycolic acid) (PLGA) nanoparticles encapsulating DOX. An avidin-biotin coupling system was used to control poly(ethylene glycol) conjugation to the surface of PLGA nanoparticles, of diameter approximately 130 nm, loaded with DOX to 5% (wt/wt). Encapsulation in nanoparticles did not compromise the efficacy of DOX; drug-loaded nanoparticles were found to be at least as potent as free DOX against A20 murine B-cell lymphoma cells in culture and of comparable efficacy against subcutaneously implanted tumors. Cardiotoxicity in mice as measured by echocardiography, serum creatine phosphokinase (CPK), and histopathology was reduced for DOX-loaded nanoparticles as compared with free DOX. Administration of 18 mg/kg of free DOX induced a sevenfold increase in CPK levels and significant decreases in left ventricular fractional shortening over control animals, whereas nanoparticle-encapsulated DOX produced none of these pathological changes. FROM THE CLINICAL EDITOR: The efficacy of doxorubicin (DOX) may be maximized and dose-limiting cardiotoxicity minimized by controlled release from PEGylated nanoparticles. Administration of 18 mg/kg of free DOX induced a sevenfold increase in CPK levels and significant decreases in left ventricular fractional shortening in mice, whereas nanoparticle-encapsulated DOX produced none of these pathological changes.

Centrifugal seeding increases seeding efficiency and cellular distribution of bone marrow stromal cells in porous biodegradable scaffolds.

Bone marrow stromal cells (MSCs) are a promising cell source for a variety of tissue engineering applications, given their ready availability and ability to differentiate into multiple cell lineages. MSCs have been successfully used to create neotissue for cardiovascular, urological, and orthopedic reconstructive surgical procedures in preclinical studies. The ability to optimize seeding techniques of MSCs onto tissue engineering scaffolds and the ability to control neotissue formation in vitro will be important for the rational design of future tissue engineering applications using MSCs. In this study we investigated the effect of centrifugal force on seeding MSCs into a biodegradable polyester scaffold. MSCs were isolated and seeded onto porous scaffold sections composed of nonwoven polyglycolic acid mesh coated with poly(L-lactide-co-epsilon-caprolactone). Compared to standard static seeding techniques, centrifugal seeding increased the seeding efficiency by 38% (p < 0.007) and significantly improved cellular distribution throughout the scaffold. Overall, centrifugal seeding of MSCs enhances seeding efficiency and improves cellular penetration into scaffolds, making it a potentially useful technique for manipulating neotissue formation by MSCs for tissue engineering applications.

Nanosystems for simultaneous imaging and drug delivery to T cells.

The T-cell response defines the pathogenesis of many common chronic disease states, including diabetes, rheumatoid arthritis, and transplant rejection. Therefore, a diagnostic strategy that visualizes this response can potentially lead to early therapeutic intervention, avoiding catastrophic organ failure or prolonged sickness. In addition, the means to deliver a drug dose to those cells in situ with the same specificity used to image those cells would provide for a powerful therapeutic alternative for many disease states involving T cells. In this report, we review emerging nanosystems that can be used for simultaneous tracking and drug delivery to those cells. Because of their versatility, these systems--which combine specific receptor targeting with an imaging agent and drug delivery--are suited to both basic science and applications, from developing therapeutic strategies for autoimmune and alloimmune diseases, to noninvasive tracking of pathogenic T-cell migration.

Construction of an autologous tissue-engineered venous conduit from bone marrow-derived vascular cells: optimization of cell harvest and seeding techniques.

BACKGROUND: Currently available vascular grafts for pediatric cardiovascular operations are limited by their inability to grow. Tissue-engineering techniques can be used to create vascular grafts with the potential for repair, remodeling, and growth. This study demonstrates the feasibility of constructing an autologous tissue-engineered venous conduit from bone marrow-derived vascular cells (BMVCs) in the ovine animal model. METHODS: Ovine mononuclear cells were isolated from the bone marrow, cultured in endothelial growth medium, and characterized with immunocytochemistry. Biodegradable tubular scaffolds were constructed from polyglycolic acid mesh coated with a copolymer of poly[epsilon-caprolactone-L-lactide]. Scaffolds were seeded at various cell concentrations and incubation times to optimize seeding conditions for the construction of an autologous venous conduit. Using optimized conditions, 6 tissue-engineered vascular grafts were implanted as inferior vena cava interposition grafts in juvenile lambs. Grafts were assessed for patency at days 1 to 30 postoperatively and explanted for histological and immunohistochemical analysis. RESULTS: A mixed cell population of BMVCs consisting of smooth muscle cells and endothelial cells was cultured from ovine sternal bone marrow. A seeding concentration of 2 x 10(6) cells/cm2 and 7 days of postseeding incubation were optimal for creating a confluent cellular layer on the polyglycolic acid/poly[epsilon-caprolactone-L-lactide]) scaffold. Grafts were explanted up to 4 weeks postoperatively. All grafts were patent without evidence of thrombosis. Histological evaluation of the explanted grafts demonstrated neo-endothelialization. Graft wall was composed of neo-tissue made up of residual polymer matrix, mesenchymal cells, and extracellular matrix without evidence of calcification. CONCLUSIONS: Bone marrow-derived vascular cells, containing endothelial and smooth muscle cells, can be isolated and cultured from ovine sternal bone marrow and used as a cell source for vascular tissue engineering. Our optimized techniques for BMVC harvest and seeding onto biodegradable scaffolds can be used for studying autologous tissue-engineered vascular grafts in the ovine animal model.

A quantitative study of magnetization transfer in MAGIC gels.

Magnetization transfer (MT) has been measured quantitatively as a function of radiation dose in MAGIC polymer gels. The MT rates between the free and immobile macromolecular proton pools (kmr and kfm), and the ratio of the sizes of these coupled proton pools (Pm/Pf), were measured by analysing the response to an inversion recovery sequence. While pm/pf increases linearly with dose, the fast MT rate kmf also increases with dose, unlike previous measurements in BANG gels. This dependence of kmf on dose suggests there are additional factors that modify spin exchange in MAGIC gels as irradiation occurs.