Ki Hyun Bae

Bioinspired Synthesis and Characterization of Gadolinium-Labeled Magnetite Nanoparticles for Dual Contrast T1- and T2-Weighted Magnetic Resonance Imaging

Gadolinium-labeled magnetite nanoparticles (GMNPs) were synthesized via a bioinspired manner to use as dual contrast agents for T1- and T2-weighted magnetic resonance imaging. A mussel-derived adhesive moiety, 3,4-dihydroxy-l-phenylalanine (DOPA), was utilized as a robust anchor to form a mixed layer of poly(ethylene glycol) (PEG) chains and dopamine molecules on the surface of iron oxide nanoparticles. Gadolinium ions were subsequently complexed at the distal end of the dopamine molecules that were prefunctionalized with a chelating ligand for gadolinium. The resultant GMNPs exhibited high dispersion stability in aqueous solution. Crystal structure and superparamagnetic properties of magnetite nanocrystals were also maintained after the complexation of gadolinium. The potential of GMNPs as dual contrast agents for T1 and T2-weighted magnetic resonance imaging was demonstrated by conducting in vitro and in vivo imaging and relaxivity measurements.

Surface functionalized hollow manganese oxide nanoparticles for cancer targeted siRNA delivery and magnetic resonance imaging

Multifunctional hollow manganese oxide nanoparticles (HMON) were produced by a bio-inspired surface functionalization approach, using 3,4-dihydroxy-L-phenylalanine (DOPA) as an adhesive moiety, for cancer targeted delivery of therapeutic siRNA and simultaneous diagnosis via magnetic resonance imaging (MRI). Cationic polyethylenimine-DOPA conjugates were stably immobilized onto the surface of HMON due to the strong binding affinity of DOPA to metal oxides, as examined by Fourier transform infrared spectroscopy and X-ray photoelectron spectroscopy. These nanoparticles were subsequently functionalized with a therapeutic monoclonal antibody, Herceptin, to selectively target cancer cells. Confocal microscopy and MR imaging studies revealed that the surface functionalized HMON enabled the targeted detection of cancer cells in T(1)-weighted MRI as well as the efficient intracellular delivery of siRNA for cell-specific gene silencing. These nanomaterials are expected to be widely exploited as multifunctional delivery vehicles for cancer therapy and imaging applications.

Nanomaterials for cancer therapy and imaging

A variety of organic and inorganic nanomaterials with dimensions below several hundred nanometers are recently emerging as promising tools for cancer therapeutic and diagnostic applications due to their unique characteristics of passive tumor targeting. A wide range of nanomedicine platforms such as polymeric micelles, liposomes, dendrimers, and polymeric nanoparticles have been extensively explored for targeted delivery of anti-cancer agents, because they can accumulate in the solid tumor site via leaky tumor vascular structures, thereby selectively delivering therapeutic payloads into the desired tumor tissue. In recent years, nanoscale delivery vehicles for small interfering RNA (siRNA) have been also developed as effective therapeutic approaches to treat cancer. Furthermore, rationally designed multi-functional surface modification of these nanomaterials with cancer targeting moieties, protective polymers, and imaging agents can lead to fabrication versatile theragnostic nanosystems that allow simultaneous cancer therapy and diagnosis. This review highlights the current state and future prospects of diverse biomedical nanomaterials for cancer therapy and imaging.

Injectable biodegradable hydrogels: progress and challenges

Over the past decades, injectable hydrogels have emerged as promising biomaterials because of their biocompatibility, excellent permeability, minimal invasion, and easy integration into surgical procedures. These systems provide an effective and convenient way to administer a wide variety of bioactive agents such as proteins, genes, and even living cells. Additionally, they can be designed to be degradable and eventually cleared from the body after completing their missions. Given their unique characteristics, injectable biodegradable hydrogels have been actively explored as drug reservoir systems for sustained release of bioactive agents and temporary extracellular matrices for tissue engineering. This review provides an overview of state-of-the-art strategies towards constructing a rational design of injectable biodegradable hydrogels for protein drug delivery and tissue engineering. We also discuss the use of injectable hydrogels for gene delivery systems and biomedical adhesives.

Heparin immobilized gold nanoparticles for targeted detection and apoptotic death of metastatic cancer cells

In the present study, heparin immobilized, multifunctional gold nanoparticles (AuNPs) were developed as a new class of theragnostic nanomaterials for metastatic cancer cell imaging and apoptosis. AuNPs were surface modified with fluorescent dye labeled heparin molecules to detect a metastatic stage of cancer cells that over-express heparin-degrading enzymes. The heparin immobilized AuNPs exhibited enhanced fluorescence signals by specific cleavage of heparin molecules from the surface of AuNPs by heparinase or heparanase secreted from metastatic cancer cells. In addition, heparin immobilized AuNPs that were additionally tethered with RGD peptides on the surface demonstrated highly specific apoptotic activities for selective cancer cells over-expressing RGD receptors on the membrane, revealing that internalized heparin within cells clearly triggered an apoptotic event. These results suggest that heparin immobilized AuNPs can be usefully exploited for optical imaging agents for metastatic tumors as well as therapeutic cancer treatment.

PEGylated and MMP-2 Specifically DePEGylated Quantum Dots: Comparative Evaluation of Cellular Uptake

Polyethylene glycol (PEG)-immobilized quantum dot (QD) nanoparticles, which could be specifically dePEGylated in response to the presence of the matrix metalloprotease-2 (MMP-2) enzyme, were prepared. The degree of PEGylation (MW 3400) on the surface of 12 nm streptavidin-coated QDs was stoichiometrically controlled by varying the feed amount of a biotin-substrate-PEG conjugate, where the substrate contained an MMP-2 cleavable peptide sequence. A biotin-cell penetrating peptide (CPP) conjugate was also immobilized onto the surface of the PEGylated QD surface to enhance the cellular uptake after dePEGylation. It was found that more than nine PEG chains per single QD were required to effectively inhibit the cellular uptake of modified QD particles down to around 20%, as compared with that of QD without PEG chains. However, the treatment of MMP-2 enzyme in the medium resulted in a substantial enhancement in the extent of QD cellular uptake by dePEGylation with concomitant resurfacing of sterically hidden CPP moieties. This study analyzed the effects of surface PEGylation density and MMP-2 specific dePEGylation on the cellular uptake of CPP-QD nanoparticles in a quantitative manner.

Synthesis, characterization, and intracellular delivery of reducible heparin nanogels for apoptotic cell death

Reducible heparin nanogels cross-linked with disulfide linkages were developed for efficient cellular uptake of therapeutic heparin to induce apoptotic cell death. The heparin nanogels were synthesized by forming nanocomplexes between thiolated heparin and poly(ethylene glycol) in a selected organic solvent, and subsequently producing intermolecular disulfide bonds between thiolated heparin molecules by ultrasonication. The resultant heparin nanogels had a stable structure with an average diameter of 248.7+/-26.8nm in aqueous solution. However, they rapidly disintegrated and released free heparin molecules under reductive environments, such as intracellular cytosol, through the cleavage of disulfide cross-links within their network structure. Confocal laser scanning microscopy and flow cytometric analysis revealed that these heparin nanogels significantly inhibited proliferation of mouse melanoma cells by inducing caspase-mediated apoptotic cell death. The present study suggested that the reducible heparin nanogels exhibiting a remarkable apoptotic activity could be potentially applied for cancer cell targeted delivery when combined with various therapeutic and diagnostic agents.

Clustered Magnetite Nanocrystals Cross-Linked with PEI for Efficient siRNA Delivery

Magnetofection has been utilized as a powerful tool to enhance gene transfection efficiency via magnetic field-enforced cellular transport processes. The accelerated accumulation of nucleic acid molecules by applying an external magnetic force enables the rapid and improved transduction efficiency. In this study, we developed magnetite nanocrystal clusters (PMNCs) cross-linked with polyethylenimine (PEI) to magnetically trigger intracellular delivery of small interfering RNA (siRNA). PMNCs were produced by cross-linked assembly of catechol-functionalized branched polyethylenimine (bPEI) around magnetite nanocrystals through an oil-in-water (O/W) emulsion and solvent evaporation method. The physical properties of PMNC were characterized by TEM, DLS, TSA, and FT-IR. Finely tuned formulation of clustered magnetite nanocrystals with controlled size and shape exhibited superior saturation of magnetization value. Magnetite nanocrystal clusters could form nanosized polyelectrolyte complexes with negatively charged siRNA molecules, enabling efficient delivery of siRNA into cells upon exposure to an external magnetic field within a short time. This study introduces a new class of magnetic nanomaterials that can be utilized for magnetically driven intracellular siRNA delivery.

Facile synthetic route for surface-functionalized magnetic nanoparticles: cell labeling and magnetic resonance imaging studies.

Currently available methods to stably disperse iron oxide nanoparticles (IONPs) in aqueous solution need to be improved due to potential aggregation, reduction of superparamagnetism, and the use of toxic reagents. Herein, we present a facile strategy for aqueous transfer and dispersion of organic-synthesized IONPs using only polyethylene glycol (PEG), a biocompatible polymer. A library of PEG derivatives was screened, and it was determined that amine-functionalized six-armed PEG, 6(PEG-NH(2)), was the most effective dispersion agent. The 6(PEG-NH(2))-modified IONPs (IONP-6PEG) were stable after extensive washing, exhibited high superparamagnetism, and could be used as a platform material for secondary surface functionalization with bioactive polymers. IONP-6PEG biofunctionalized with hyaluronic acid (IONP-6PEG-HA) was shown to specifically label mesenchymal stem cells and demonstrate MR contrast potential with high r(2) relaxivity (442.7 s(-1)mM(-1)) compared to the commercially available Feridex (182.1 s(-1)mM(-1)).

Fabrication of hyaluronic acid hydrogel beads for cell encapsulation.

Hyaluronic acid (HA) hydrogel beads were prepared by photopolymerization of methacrylated HA and N‐vinylpyrrolidone using alginate as a temporal spherical mold. Various fabrication conditions for preparing the hydrogel beads, such as the concentration of methacrylated HA and UV irradiation time, were optimized to control swelling properties and enzymatic degradability. A new concept for cell encapsulation is proposed in this paper. Viable cells were directly injected into the hydrogel beads using a microinjection technique. When bovine articular chondrocytes were injected into HA hydrogel beads and cultivated for 1 week, the cells could proliferate well within the HA beads. HA hydrogel beads could be potentially used as injectable cell delivery vehicles for regenerating tissue defects.