Oju Jeon

Photocrosslinked alginate hydrogels with tunable biodegradation rates and mechanical properties.

Photocrosslinked and biodegradable alginate hydrogels were engineered for biomedical applications. Photocrosslinkable alginate macromers were prepared by reacting sodium alginate and 2-aminoethyl methacrylate in the presence of 1-ethyl-3-(3-dimethylaminopropyl)-carbodiimide hydrochloride and N-hydroxysuccinimide. Methacrylated alginates were photocrosslinked using ultraviolet light with 0.05% photoinitiator. The swelling behavior, elastic moduli, and degradation rates of photocrosslinked alginate hydrogels were quantified and could be controlled by varying the degree of alginate methacrylation. The methacrylated alginate macromer and photocrosslinked alginate hydrogels exhibited low cytotoxicity when cultured with primary bovine chondrocytes. In addition, chondrocytes encapsulated in these hydrogels remained viable and metabolically active as demonstrated by Live/Dead cell staining and MTS assay. These photocrosslinked alginate hydrogels, with tailorable mechanical properties and degradation rates, may find great utility as therapeutic materials in regenerative medicine and bioactive factor delivery.

Long-term delivery enhances in vivo osteogenic efficacy of bone morphogenetic protein-2 compared to short-term delivery.

In this study, heparin-conjugated poly(l-lactide-co-glycolide) (PLGA) nanospheres (HCPNs) suspended in fibrin gel (group 1) were developed for a long-term delivery of BMP-2, and then used to address the hypothesis that a long-term delivery of BMP-2 would enhance ectopic bone formation compared to a short-term delivery at an equivalent dose. Fibrin gel containing normal PLGA nanospheres (group 2) was used for short-term delivery of BMP-2. The in vitro release of BMP-2 from group 1 was sustained for 4 weeks with no initial burst release. In contrast, 83% of BMP-2 loaded in group 2 was released only for the first 3 days. BMP-2 released from group 1 stimulated an increase in alkaline phosphatase (ALP) activity of osteoblasts for 9 days in vitro. In contrast, BMP-2 released from group 2 induced a transient increase in ALP activity for the first 5 days and a decrease thereafter. Importantly, group 1 induced bone formation to a much greater extent than did group 2, with 2.0-fold greater bone formation area and 3.5-fold greater calcium content, upon implantation into rat hind limb muscle. These results show that long-term delivery of BMP-2 enhances in vivo osteogenic efficacy of the protein compared to short-term delivery at an equivalent dose.

Affinity-based growth factor delivery using biodegradable, photocrosslinked heparin-alginate hydrogels

Photocrosslinkable biomaterials are promising for tissue engineering applications due to their capacity to be injected and form hydrogels in situ in a minimally invasive manner. Our group recently reported on the development of photocrosslinked alginate hydrogels with controlled biodegradation rates, mechanical properties, and cell adhesive properties. In this study, we present an affinity-based growth factor delivery system by incorporating heparin into photocrosslinkable alginate hydrogels (HP-ALG), which allows for controlled, prolonged release of therapeutic proteins. Heparin modification had minimal effect on the biodegradation profiles, swelling ratios, and elastic moduli of the hydrogels in media. The release profiles of growth factors from this affinity-based platform were sustained for 3weeks with no initial burst release, and the released growth factors retained their biological activity. Implantation of bone morphogenetic protein-2 (BMP-2)-loaded photocrosslinked alginate hydrogels induced moderate bone formation around the implant periphery. Importantly, BMP-2-loaded photocrosslinked HP-ALG hydrogels induced significantly more osteogenesis than BMP-2-loaded photocrosslinked unmodified alginate hydrogels, with 1.9-fold greater peripheral bone formation and 1.3-fold greater calcium content in the BMP-2-loaded photocrosslinked HP-ALG hydrogels compared to the BMP-2-loaded photocrosslinked unmodified alginate hydrogels after 8weeks implantation. This sustained and controllable growth factor delivery system, with independently controllable physical and cell adhesive properties, may provide a powerful modality for a variety of therapeutic applications.

Localized and sustained delivery of silencing RNA from macroscopic biopolymer hydrogels.

The ability to silence the expression of specific genes at a particular location of the body would provide a powerful new therapeutic tool for treatment of diseases such as cancer or for use in regenerative medicine. RNA interference (RNAi) is a gene silencing mechanism where specific mRNA molecules that are complementary to short interfering RNA (siRNA) are degraded, thus inhibiting gene expression at the post-transcriptional level. However, the use of siRNA has not yet realized its full clinical potential due to degradation in vivo, the difficulty retaining siRNA at the site of interest, and the relatively short-term effect it has on rapidly dividing cells. In this work a new paradigm is presented that will allow for the localized delivery of siRNA that is controlled and sustained over time, thus allowing cells at the site of interest to be directly exposed to a gradual release of bioactive siRNA. To accomplish this, three different types of macroscopic, degradable biomaterial hydrogel scaffolds were employed: calcium crosslinked alginate, photocrosslinked alginate, and collagen. Differing rates of release from these hydrogels were achieved, and the ability of the released siRNA to knock down the expression of GFP in cells that constitutively express this protein was shown. Furthermore, the ability to encapsulate cells within these materials and achieve sustained gene silencing of these incorporated cells was demonstrated. These biopolymer hydrogels are injectable and, therefore, can be delivered in a minimally invasive manner, and they can serve as delivery vehicles for both siRNA and transplanted cell populations.

In Vivo Bone Formation Following Transplantation of Human Adipose–Derived Stromal Cells That Are Not Differentiated Osteogenically

A number of studies have shown in vivo bone regeneration by transplantation of osteogenic cells differentiated in vitro from adipose-derived stromal cells (ADSCs). However, the in vitro osteogenic differentiation process requires an additional culture period, and the dexamethasone that is generally used in the process may be cytotoxic. Here, we tested the hypothesis that ADSCs that are not differentiated osteogenically in vitro prior to transplantation would extensively regenerate bone in vivo when exogenous bone morphogenetic protein-2 (BMP-2) is delivered to the transplantation site. We fabricated a poly(dl-lactic-co-glycolic acid)/hydroxyapatite (PLGA/HA) composite scaffold with osteoactive HA that is highly exposed on the scaffold surface. This scaffold was able to release BMP-2 over a 4-week period in vitro. Human ADSCs cultured on BMP-2-loaded PLGA/HA scaffolds for 2 weeks differentiated toward osteogenic cells expressing alkaline phosphatase (ALP), osteopontin (OPN), and osteocalcin (OCN) mRNA, while cells on PLGA/HA scaffolds without BMP-2 expressed only ALP. To study in vivo bone formation, PLGA/HA scaffolds (group 1), BMP-2-loaded PLGA/HA scaffolds (group 2), undifferentiated ADSCs seeded on PLGA/HA scaffolds (group 3), and undifferentiated ADSCs seeded on BMP-2-loaded PLGA/HA scaffolds (group 4) were implanted into dorsal, subcutaneous spaces of athymic mice. Eight weeks after implantation, group 4 exhibited a 25-fold greater bone formation area and 5-fold higher calcium deposition than group 3. Bone regeneration by transplanted human ADSCs in group 4 was confirmed by expression of human-specific osteoblastic genes, ALP, collagen type I, OPN, OCN, and bone sialoprotein, while group 3 expressed much lower levels of collagen type I and OPN mRNA only. This study demonstrates the feasibility of extensive in vivo bone regeneration by transplantation of ADSCs without prior in vitro osteogenic differentiation, and that a PLGA/HA composite BMP-2 delivery system stimulates bone regeneration following transplantation of undifferentiated human ADSCs.

Sustained localized presentation of RNA interfering molecules from in situ forming hydrogels to guide stem cell osteogenic differentiation.

To date, RNA interfering molecules have been used to differentiate stem cells on two-dimensional (2D) substrates that do not mimic three-dimensional (3D) microenvironments in the body. Here, in situ forming poly(ethylene glycol) (PEG) hydrogels were engineered for controlled, localized and sustained delivery of RNA interfering molecules to differentiate stem cells encapsulated within the 3D polymer network. RNA interfering molecules were released from the hydrogels in a sustained and controlled manner over the course of 3-6 weeks, and exhibited high bioactivity. Importantly, it was demonstrated that the delivery of siRNA and/or miRNA from the hydrogel constructs enhanced the osteogenic differentiation of encapsulated stem cells. Prolonged delivery of siRNA and/or miRNA from this polymeric scaffold permitted extended regulation of cell behavior, unlike traditional siRNA experiments performed in vitro. This approach presents a powerful new methodology for controlling cell fate, and is promising for multiple applications in tissue engineering and regenerative medicine.

Suspension culture of mammalian cells using thermosensitive microcarrier that allows cell detachment without proteolytic enzyme treatment.

Microcarriers are used to expand anchorage-dependent cells in large-scale suspension bioreactors. Proteolytic enzyme treatment is necessary to detach cells cultured on microcarriers for cell harvest or scale-up, but the enzyme treatment damages the cells and extracellular matrices and complicates the culture process. Here, we fabricated thermosensitive microcarriers from which cells can be detached by temperature change without proteolytic enzyme treatment. A thermosensitive polymer, poly-N-isopropylacrylamide (pNIPAAm), was incorporated on the surface of Cytodex-3® microcarriers. pNIPAAm-grafted microcarriers allowed human bone marrow-derived mesenchymal stem cells (hBMMSCs) to adhere, spread, and grow successfully on the microcarriers as nongrafted microcarriers did. By dropping temperature below 32°C, more than 82.5% of hBMMSCs were detached from pNIPAAm-grafted microcarriers. The trypsin treatment for cell detachment induced apoptosis and death of some of the detached cells, but cell detachment from pNIPAAm-grafted microcarriers by temperature change significantly reduced the apoptosis and cell death. pNIPAAm-grafted microcarriers can significantly reduce cell extracellular matrix damage in the cell detachment process and simplify the cell detachment process by avoiding proteolytic enzyme treatment. pNIPAAm-grafted microcarriers would be valuable to a variety of potential fields demanding a large amount of cells without cell damage, such as cell therapy, tissue engineering, and other biological and clinical applications.

Single and dual crosslinked oxidized methacrylated alginate/PEG hydrogels for bioadhesive applications

A degradable, cytocompatible bioadhesive can facilitate surgical procedures and minimize patient pain and post-surgical complications. In this study a bioadhesive hydrogel system based on oxidized methacrylated alginate/8-arm poly(ethylene glycol) amine (OMA/PEG) has been developed, and the bioadhesive characteristics of the crosslinked OMA/PEG hydrogels evaluated. Here we demonstrate that the swelling behavior, degradation profiles, and storage moduli of crosslinked OMA/PEG hydrogels are tunable by varying the degree of alginate oxidation. The crosslinked OMA/PEG hydrogels exhibit cytocompatibility when cultured with human bone marrow-derived mesenchymal stem cells. In addition, the adhesion strength of these hydrogels, controllable by varying the alginate oxidation level and measured using a porcine skin model, is superior to commercially available fibrin glue. This OMA/PEG hydrogel system with controllable biodegradation and mechanical properties and adhesion strength may be a promising bioadhesive for clinical use in biomedical applications, such as drug delivery, wound closure and healing, biomedical device implantation, and tissue engineering.

Poly(L-lactide-co-glycolide) nanospheres conjugated with a nuclear localization signal for delivery of plasmid DNA.

Polymeric nanospheres fabricated from biodegradable poly(lactide-co-glycolide) (PLGA) have been extensively investigated for applications in gene delivery. In this study, we show that the covalent conjugation of a nuclear localization signal (NLS, SV40 peptide) on PLGA nanospheres enhances the gene transfection efficiency. NLS conjugated PLGA copolymer was prepared by using a coupling reaction between maleimide-terminated PLGA copolymer and NLS in the presence of Imject maleimide conjugation buffer. PLGA nanospheres encapsulating plasmid (pDNA) were prepared by using a double emulsion-solvent evaporation method. The kinetics of in vitro release of pDNA from PLGA nanospheres was determined with UV in phosphate buffered saline (PBS). Gene transfection efficiency in human dermal fibroblasts was tested in vitro using nanospheres encapsulating the luciferase gene. The conjugation of the NLS peptide to the PLGA nanospheres could improve the nuclear localization and/or cellular uptake of PLGA nanosphere/pDNA constructs and thereby improve the transfection efficiency of a PLGA nanosphere gene delivery system. The pDNA was released from PLGA nanospheres over nine days. NLS conjugation enhanced the gene transfection efficiency in vitro by 1.2 ∼ 3.2-fold over 13 days. PLGA/pDNA nanospheres appeared to be superior to PEI/pDNA complexes for the long-term expression of pDNA. Furthermore, the level of the sustained gene expression of the PLGA nanospheres was enhanced by the conjugation of NLS to the PLGA nanospheres. This study showed that the NLS conjugation enhanced the gene transfection efficiency of the PLGA nanosphere gene delivery system in vitro and that the enhanced gene expression was sustained for at least 13 days.

3D Bioprinting of Developmentally Inspired Templates for Whole Bone Organ Engineering.

The ability to print defined patterns of cells and extracellular-matrix components in three dimensions has enabled the engineering of simple biological tissues; however, bioprinting functional solid organs is beyond the capabilities of current biofabrication technologies. An alternative approach would be to bioprint the developmental precursor to an adult organ, using this engineered rudiment as a template for subsequent organogenesis in vivo. This study demonstrates that developmentally inspired hypertrophic cartilage templates can be engineered in vitro using stem cells within a supporting gamma-irradiated alginate bioink incorporating Arg-Gly-Asp adhesion peptides. Furthermore, these soft tissue templates can be reinforced with a network of printed polycaprolactone fibers, resulting in a ≈350 fold increase in construct compressive modulus providing the necessary stiffness to implant such immature cartilaginous rudiments into load bearing locations. As a proof-of-principal, multiple-tool biofabrication is used to engineer a mechanically reinforced cartilaginous template mimicking the geometry of a vertebral body, which in vivo supported the development of a vascularized bone organ containing trabecular-like endochondral bone with a supporting marrow structure. Such developmental engineering approaches could be applied to the biofabrication of other solid organs by bioprinting precursors that have the capacity to mature into their adult counterparts over time in vivo.