Hyo Jung Moon

3D Culture of Adipose-Tissue-Derived Stem Cells Mainly Leads to Chondrogenesis in Poly(ethylene glycol)-Poly(l-alanine) Diblock Copolymer Thermogel

Poly(ethylene glycol)-b-poly(L-alanine) (PEG-L-PA)s with L-PA molecular weights of 620, 1100, and 2480 Da and a fixed molecular weight of PEG at 5000 Da were synthesized to compare the thermosensitive behavior, and to investigate their potential as a three-dimensional (3D) culture matrix of adipose-tissue-derived stem cells (ADSCs). The sol-to-gel transition temperature and the concentration ranges where the transition was observed decreased as the L-PA molecular weight increased. ADSCs were cultured in the 3D matrixes of in situ formed PEG-L-PA hydrogels, which were produced by increasing the temperature of cell-suspended PEG-L-PA aqueous solutions. The spherical morphology was maintained in the PEG-L-PA hydrogel, while the cells underwent fibroblastic morphological changes in the Matrigel over 14 days of incubation. ADSCs exhibited high expression of type II collagen in the PEG-L-PA thermogel. In addition, they also moderately expressed the biomarker of myogenic differentiation factor 1 as the same mesodermal lineages, as well as the type III β-tubulin as a cross-differentiation biomarker. Similar to the in vitro study, the ADSCs predominantly exhibited chondrogenic biomarkers in the in vivo study. The study demonstrates that the polypeptide thermogel of PEG-L-PA is promising as a 3D culture matrix of ADSCs and as an injectable tissue engineering biomaterial.

Enzymatically degradable thermogelling poly(alanine-co-leucine)-poloxamer-poly(alanine-co-leucine).

In the search for an enzymatically degradable thermogelling system, we are reporting poly(alanine-co-leucine)-poloxamer-poly(alanine-co-leucine) (PAL-PLX-PAL) aqueous solution. As the temperature increased, the polymer aqueous solution underwent sol-to-gel transition at 20-40 °C in a polymer concentration range of 3.0-10.0 wt %. The amphiphilic polymers of PAL-PLX-PAL form micelles in water, where the hydrophobic PALs form a core and the hydrophilic PLXs form a shell of the micelle. FTIR, circular dichroism, and (13)C NMR spectra suggest that the α-helical secondary structure of PAL is preserved; however, the molecular motion of the PLX significantly decreases in the sol-to-gel transition range of 20-50 °C. The polymer was degraded by proteolytic enzymes such as matrix metalloproteinase and elastase, whereas it was quite stable against cathepsin B, cathepsin C, and chymotrypsin or in phosphate-buffered saline (control). The in situ formed gel in the subcutaneous layer of rats showed a duration of ∼ 47 days, and H&E staining study suggests the histocompatibility of the gel in vivo with a marginal inflammation response of capsule formation. A model drug of bovine serum albumin was released over 1 month by the preset-gel injection method. The thermogelling PAL-PLX-PAL can be a promising biocompatible material for minimally invasive injectable drug delivery.

3D Culture of Tonsil-Derived Mesenchymal Stem Cells in Poly(ethylene glycol)-Poly(l-alanine-co-l-phenyl alanine) Thermogel

Poly(ethylene glycol)-poly(L-alanine-co-L-phenyl alanine) (PEG-PAF) aqueous solutions undergo sol-to-gel transition as the temperature increases. The transition is driven by the micelle aggregation involving the partial dehydration of the PEG block and the partial increase in β-sheet content of the PAF block. Tonsil-tissue-derived mesenchymal stem cells (TMSCs), a new stem cell resource, are encapsulated through the sol-to-gel transition of the TMSC-suspended PEG-PAF aqueous solutions. The encapsulated TMSCs are in vitro 3D cultured by using induction media supplemented with adipogenic, osteogenic, or chondrogenic factors, where the TMSCs preferentially undergo chondrogenesis with high expressions of type II collagen and sulfated glycosaminoglycan. As a feasibility study of the PEG-PAF thermogel for injectable tissue engineering, the TMSCs encapsulated in hydrogels are implanted in the subcutaneous layer of mice by injecting the TMSC suspended PEG-PAF aqueous solution. The in vivo studies also prove that TMSCs undergo chondrogenesis with high expression of the chondrogenic biomarkers. This study suggests that the TMSCs can be an excellent resource of MSCs, and the thermogelling PEG-PAF is a promising injectable tissue engineering scaffold, particularly for chondrogenic differentiation of the stem cells.

Composite System of Graphene Oxide and Polypeptide Thermogel As an Injectable 3D Scaffold for Adipogenic Differentiation of Tonsil-Derived Mesenchymal Stem Cells.

As two-dimensional (2D) nanomaterials, graphene (G) and graphene oxide (GO) have evolved into new platforms for biomedical research as biosensors, imaging agents, and drug delivery carriers. In particular, the unique surface properties of GO can be an important tool in modulating cellular behavior and various biological sequences. Here, we report that a composite system of graphene oxide/polypeptide thermogel (GO/P), prepared by temperature-sensitive sol-to-gel transition of a GO-suspended poly(ethylene glycol)-poly(L-alanine) (PEG-PA) aqueous solution significantly enhances the expression of adipogenic biomarkers, including PPAR-γ, CEBP-α, LPL, AP2, ELOVL3, and HSL, compared to both a pure hydrogel system and a composite system of G/P, graphene-incorporated hydrogel. We prove that insulin, an adipogenic differentiation factor, preferentially adhered to GO, is supplied to the incorporated stem cells in a sustained manner over the three-dimensional (3D) cell culture period. On the other hand, insulin is partially denatured in the presence of G and interferes with the adipogenic differentiation of the stem cells. The study suggests that a 2D/3D composite system is a promising platform as a 3D cell culture matrix, where the surface properties of 2D materials in modulating the fates of the stem cells are effectively transcribed in a 3D culture system.

Sol–gel transition of PEG–PAF aqueous solution and its application for hGH sustained release

We report a poly(ethylene glycol)–poly(L-alanine-co-L-phenylalanine) (PEG–PAF) aqueous solution as a polypeptide-based thermogelling system and its application as an injectable sustained release system for human growth hormone (hGH). The PEG–PAF aqueous solution underwent sol-to-gel transition at 16–34 °C in a polymer concentration range of 6.0–14.0 wt% as the temperature increased. Dynamic light scattering, circular dichroism, FTIR, and 13C-NMR spectra indicated that the secondary structure of PAF was preserved, however, PEG was dehydrated in the sol-to-gel transition temperature range. A micelle aggregation model was suggested for the sol-to-gel transition of the current PEG–PAF, similar to previous polyesters. The polymer was quite stable in water, and therefore, the molecular weight of the polymer did not significantly change and pH of the aqueous polymer solution was maintained at 7.2–7.8 during the 1 month storage of the polymer as an aqueous solution at room temperature. This point is clearly distinguished from previous thermogelling polymers based on polyesters, polyorthoesters, polyphosphazenes, poly(β-aminoester urethane)s, and polyanhydrides, which generate acid degradation products or can be degraded during storage as an aqueous polymer solution. Therefore, the current system can be used as a ready-to-use injectable implant for biomedical applications. When the polymer aqueous solution (0.5 mL) was injected into the subcutaneous layer of rats, the gel was formed by temperature-sensitive sol-to-gel transition, and the gel was completely eliminated from the implanted site in 1–5 ng mL−1in vivo, suggesting that the system is promising as a once-per-week delivery system for the hGH.

Polypeptide Thermogels as a Three Dimensional Culture Scaffold for Hepatogenic Differentiation of Human Tonsil-Derived Mesenchymal Stem Cells

Tonsil-derived mesenchymal stem cells (TMSCs) were investigated for hepatogenic differentiation in the 3D matrixes of poly(ethylene glycol)-b-poly(l-alanine) (PEG-L-PA) thermogel. The diblock polymer formed β-sheet based fibrous nanoassemblies in water, and the aqueous polymer solution undergoes sol-to-gel transition as the temperature increases in a concentration range of 5.0-8.0 wt %. The cell-encapsulated 3D matrix was prepared by increasing the temperature of the cell-suspended PEG-L-PA aqueous solution (6.0 wt %) to 37 °C. The gel modulus at 37 °C was about 1000 Pa, which was similar to that of decellularized liver tissue. Cell proliferation, changes in cell morphology, hepatogenic biomarker expressions, and hepatocyte-specific biofunctions were compared for the following 3D culture systems: TMSC-encapsulated thermogels in the absence of hepatogenic growth factors (protocol M), TMSC-encapsulated thermogels where hepatogenic growth factors were supplied from the medium (protocol MGF), and TMSC-encapsulated thermogels where hepatogenic growth factors were coencapsulated with TMSCs during the sol-to-gel transition (protocol GGF). The spherical morphology and size of the encapsulated cells were maintained in the M system during the 3D culture period of 28 days, whereas the cells changed their morphology and significant aggregation of cells was observed in the MGF and GGF systems. The hepatocyte-specific biomarker expressions and metabolic functions were negligible for the M system. However, hepatogenic genes of albumin, cytokeratin 18 (CK-18), and hepatocyte nuclear factor 4α (HNF 4α) were significantly expressed in both MGF and GGF systems. In addition, production of albumin and α-fetoprotein was also significantly observed in both MGF and GGF systems. The uptake of cardiogreen and low-density lipoprotein, typical metabolic functions of hepatocytes, was apparent for MGF and GGF. The above data indicate that the 3D culture system of PEG-L-PA thermogels provides cytocompatible microenvironments for hepatogenic differentiation of TMSCs. In particular, the successful results of the GGF system suggest that the PEG-L-PA thermogel can be a promising injectable tissue engineering system for liver tissue regeneration after optimizing the aqueous formulation of TMSCs, hepatogenic growth factors, and other biochemicals.

Thermogelling Chitosan-g-(PAF-PEG) Aqueous Solution As an Injectable Scaffold

The present study reports on a thermogelling poly(ethylene glycol)-poly(L-alanine-co-L-phenyl alanine) grafted chitosan (CS-g-(PAF-PEG)) system, focusing on phase diagram, transition mechanism, and in vivo gel duration. The sol-to-gel transition temperature decreased from 27 to 11 °C as the concentration increased from 4.0 wt % to 9.0 wt %. The polymer formed micelles with 10-50 nm in diameter at 10 °C and formed large aggregates ranging from hundreds to thousands of nanometers in size as the temperature increased from 10 to 35 °C, suggesting that an extensive molecular aggregation might be involved in the sol-to-gel transition. To study the transition mechanism on a molecular level, we investigated pH, circular dichroism spectra, and (13)C NMR spectra of the CS-g-(PAF-PEG) aqueous solution as a function of temperature. As the temperature increased, deprotonation of the chitosan and dehydration of the PEG were suggested, whereas the α-helical secondary structure of PAF was slightly changed in the sol-to-gel transition temperature range of 10-50 °C. A gel was formed in situ after injecting the CS-g-(PAF-PEG) aqueous solution into the subcutaneous layer of rats. About 60-70% of the gel was eliminated in 1 week, and the remaining gel was completely cleared from the implant site in 14 days. The results indicate the potential of CS-g-(PAF-PEG) as a promising short-term carrier for pharmaceutical agents.

PEG‐Poly(l‐alanine) Thermogel As a 3D Scaffold of Bone‐Marrow‐Derived Mesenchymal Stem Cells

Bone-marrow-derived mesenchymal stem cells (BMSCs) were cultured in three-dimensional (3D) scaffolds formed by temperature-sensitive sol-to-gel transition of BMSC-suspended poly(ethylene glycol)-poly(L-alanine) (PEG-PA) aqueous solutions. A commercialized thermogelling 3D scaffold of Matrigel™ was used for the comparative study. The cells maintained their spherical shapes in the PEG-PA thermogel, whereas fibrous cell morphologies were observed in the Matrigel™. Type II collagen and myogenic differentiation factor 1 were dominantly expressed in the PEG-PA thermogel. On the other hand, a significant extent of type III β-tubulin was expressed in the Matrigel™ in addition to type II collagen and myogenic differentiation factor 1. After confirming the dominant chondrogenic differentiation of the BMSCs in the PEG-PA thermogel in in vitro study, in vivo study was performed for injectable tissue engineering application of the BMSCs/PEG-PA system. The cell-growing implant was formed in situ by subcutaneous injection of the BMSC-suspended PEG-PA aqueous solution to mice. In vivo study also proved the excellent expressions of chondrogenic biomarkers including collagen type II and sulfated glycosaminoglycan in the mouse model. This paper suggests that the PEG-PA thermogel is a very promising as a 3D culture matrix as well as an injectable tissue-engineering system for preferential chondrogenic differentiation of the BMSCs.

CO2- and O2-Sensitive Fluorophenyl End-Capped Poly(ethylene glycol)

Pentafluorophenyl end-capped poly(ethylene glycol) (PF-PEG-PF) aqueous solution shows a lower critical solution temperature (LCST), which is sensitive to the type of gases dissolved in the solution. LCST increases from 24.5 to 26 °C when dissolved carbon dioxide is replaced by oxygen. The transparent-to-turbid transition is reversibly observed when the dissolved carbon dioxide in the PF-PEG-PF aqueous solution is exchanged with oxygen, and vice versa, at 24.5 °C. (19) F NMR and (1) H NMR spectra of the PF-PEG-PF in D2 O suggest that 1) dehydration of PEG is the main reason of developing LCST of the PF-PEG-PF aqueous solution, 2) minute differences in the intermolecular interactions, as demonstrated by changes in the chemical shift of the PF-PEG-PF peaks, induce such a difference in LCST. This paper provides a new insight in designing a stimuli-responsive polymer in that fine tuning of a phase transition can be controlled by the type of dissolved gas.

Block sequence affects thermosensitivity and nano-assembly: PEG-L-PA-DL-PA and PEG-DL-PA-L-PA block copolymers

We are reporting triblock copolymers of (ethylene glycol)44–(L-alanine)9–(DL-alanine)9 (PEG–L-PA–DL-PA) with α-helical L-PA localized between flexible PEG and DL-PA, and (ethylene glycol)44–(DL-alanine)9–(L-alanine)9 (PEG–DL-PA–L-PA) with gradient flexibility in water. Aqueous solutions of PEG–L-PA–DL-PA underwent only sol-to-gel transition, whereas those of PEG-DL-PA-L-PA underwent sol-to-gel-to-squeezed gel transitions as the temperature increased. The L-PAs of both polymers have an α-helical secondary structure in water at low temperature. However, the α-helical structure of the PEG-DL-PA-L-PA changed into a random coil structure as the temperature increased above 40 °C, whereas the PEG-L-PA-DL-PA kept the α-helical secondary structure over the same investigated temperature range of 4 °C to 50 °C. Cryo-transmission electron microscopy images and dynamic light scattering suggested that the PEG-L-PA-DL-PA develops spherical micelles, whereas the PEG-DL-PA-L-PA develops cylindrical bundles as well as spherical micelles in water. Even though both block copolymers have a similar composition of (ethylene glycol)44, (L-alanine)9, and (DL-alanine)9, they showed significantly different temperature-sensitivities as well as different nano-assemblies in water. This report suggests that the block sequence of a polymer is very important in developing a specific nano-structure as well as in controlling thermosensitivity of the polymer, thus providing useful molecular information in designing a biomaterial.