Si Nae Park scite author profile

The aim of this study was to develop platelet-derived growth factor (PDGF-BB) loaded moldable porous poly (L-lactide) (PLLA)-tricalcium phosphate (TCP) membranes for guided bone regeneration (GBR) therapy. The membranes were designed to fit various types of bone defect sites. PDGF-BB-dissolved PLLA-TCP in methylene chloride-ethyl acetate solution was cast on a dome shaped metallic mold to fabricate a model membrane. The release rate of PDGF-BB, the osteoblast attachment test, and guided bone regeneration potential were evaluated with PDGF-BB-loaded PLLA-TCP membranes. Regular pores were generated throughout the membrane mainly due to phase inversion of PLLA-methylene chloride-ethyl acetate solution. A therapeutic amount of PDGF-BB was released from the membrane. The release rate could be controlled by varying the initial loading content of PDGF-BB. A significant amount of cells attached onto the PDGF-BB-loaded membrane rather than onto the unloaded membrane. Dome shaped bone formation was achieved in rabbit calvaria at 4 weeks. This indicated that restoration of bone defects to the bone's original shape can be made possible by using molded membranes, which guide bone regeneration along with providing sufficient spaces. Bone forming efficiency was increased remarkably due to PDGF-BB release from PLLA-TCP membranes. These results suggested that the PDGF-BB releasing molded PLLA-TCP membrane may potentially improve GBR efficiency in various types of bone defects.

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Molecular diagnosis of hereditary spherocytosis by multi-gene target sequencing in Korea: matching with osmotic fragility test and presence of spherocyte

Choi

Kim

et al. 2019

Orphanet J Rare Dis

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Background Current diagnostic tests for hereditary spherocytosis (HS) focus on the detection of hemolysis or indirectly assessing defects of membrane protein, whereas direct methods to detect protein defects are complicated and difficult to implement. In the present study, we investigated the patterns of genetic variation associated with HS among patients clinically diagnosed with HS. Methods Multi-gene targeted sequencing of 43 genes (17 RBC membrane protein-encoding genes, 20 RBC enzyme-encoding genes, and six additional genes for the differential diagnosis) was performed using the Illumina HiSeq platform. Results Among 59 patients with HS, 50 (84.7%) had one or more significant variants in a RBC membrane protein-encoding genes. A total of 54 significant variants including 46 novel mutations were detected in six RBC membrane protein-encoding genes, with the highest number of variants found in SPTB ( n = 28), and followed by ANK1 ( n = 19), SLC4A1 ( n = 3), SPTA1 ( n = 2), EPB41 ( n = 1), and EPB42 ( n = 1). Concurrent mutations of genes encoding RBC enzymes ( ALDOB, GAPDH, and GSR ) were detected in three patients. UGT1A1 mutations were present in 24 patients (40.7%). Positive rate of osmotic fragility test was 86.8% among patients harboring HS-related gene mutations. Conclusions This constitutes the first large-scaled genetic study of Korean patients with HS. We demonstrated that multi-gene target sequencing is sensitive and feasible that can be used as a powerful tool for diagnosing HS. Considering the discrepancies of clinical and molecular diagnoses of HS, our findings suggest that molecular genetic analysis is required for accurate diagnosis of HS. Electronic supplementary material The online version of this article (10.1186/s13023-019-1070-0) contains supplementary material, which is available to authorized users.

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Enhanced guided bone regeneration by controlled tetracycline release from poly(L-lactide) barrier membranes

Park

Lee

Park

et al. 2000

J. Biomed. Mater. Res.

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With the aim of providing effective periodontal therapeutic modality, drug-releasing membranes for guided tissue regeneration (GTR) were developed. As GTR membranes, biodegradable barrier membranes composed of porous poly(L-lactide) (PLLA) films cast on poly(glycolide) (PGA) meshes were fabricated using an in-air drying phase inversion technique. PLLA was dissolved in methylene chloride-ethylacetate mixtures, cast on knitted PGA mesh, and then air-dried. Tetracycline, which is used in periodontal therapy because of its antibacterial activity and tissue regenerating effects, including osteoblast chemotactic effect and anti-collagenolytic activity, was incorporated into the membranes by adding it to PLLA solutions. The guided bone regenerating potential of tetracycline-loaded membranes was evaluated using release kinetics both in vitro and in vivo, biodegradation tests, and cell attachment tests. Homogeneous pores were generated both at the surface and in a sublayer of the membranes. The release kinetics of tetracycline depended mainly upon the hydrophilicity of tetracycline and the porosity of the membrane. The release rate further could be controlled by loaded drug contents. The release of tetracycline was appropriate for maintaining anti-microbial activity and for its tissue-regenerating potential. The membranes retained a proper degradation property, maintaining their mechanical integrity for the barrier function for 4 weeks. Tetracycline-loaded membranes induced increased cell attachment levels compared with those of unloaded membranes. Tetracycline-loaded membranes markedly increased new bone formation in rat calvarial defects and induced bony reunion after 2 weeks of implantation. These results suggest that tetracycline-loaded PLLA membranes potentially enhance guided tissue regenerative efficacy.

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CALR, JAK2, and MPL Mutation Profiles in Patients With Four Different Subtypes of Myeloproliferative Neoplasms

Kim

Park

et al. 2015

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Time‐dependent Modulation of Alignment and Differentiation of Smooth Muscle Cells Seeded on a Porous Substrate Undergoing Cyclic Mechanical Strain

et al. 2006

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The orientation of cellular alignment in smooth muscle tissue engineering is directly related to optimal movement of engineered tissue when it is transplanted in vivo. Cyclic mechanical strain has been applied to modulate the alignment, proliferation, and differentiation of smooth muscle cells. This study was conducted to investigate the effects of cyclic mechanical strain on primary cultured myofibroblasts seeded onto three-dimensional polymeric scaffolds, and to determine the optimal mechanical treatment time required to produce artificial smooth muscle. The cells were primary cultured from rabbit esophageal smooth muscle layer, and a self-designed stretching chamber was used to modulate the cells on porous polyurethane (PU) scaffolds with 10% strain at a frequency of 1 Hz. The applied cyclic strain induced cellular alignment. In particular, cellular alignment perpendicular to the direction of strain was generated in the condition strained over 18 h. In terms of proliferation, the strained groups differed significantly from the statically cultured group, but no difference was observed between groups that were subjected to straining for different lengths of time. Quantitative analysis of alpha-smooth muscle actin (SMA) showed that differentiation was significantly promoted at 18 h of strain. Penetration of primary cultured cells into the pores of PU scaffolds was shown after cyclic strain application, especially in 18 and 24 h of strain. Consequently, it is expected that myofibroblast/scaffold hybrids, cyclically strained in the defined time course, could be practically applied to organize functional smooth muscle tissues having consistent cell alignment and up-regulated SMA.

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Si Nae Park

Molded porous poly (L-lactide) membranes for guided bone regeneration with enhanced effects by controlled growth factor release

Molecular diagnosis of hereditary spherocytosis by multi-gene target sequencing in Korea: matching with osmotic fragility test and presence of spherocyte

Enhanced guided bone regeneration by controlled tetracycline release from poly(L-lactide) barrier membranes

CALR, JAK2, and MPL Mutation Profiles in Patients With Four Different Subtypes of Myeloproliferative Neoplasms

Time‐dependent Modulation of Alignment and Differentiation of Smooth Muscle Cells Seeded on a Porous Substrate Undergoing Cyclic Mechanical Strain

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