Azizah Intan Pangesty scite author profile

Azizah Intan Pangesty

5Publications

27Citation Statements Received

77Citation Statements Given

How they've been cited

How they cite others

146

Affiliations

University of Indonesia, Kyushu University, Material Sciences (United States)

Publications

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Development and characterization of hybrid tubular structure of PLCL porous scaffold with hMSCs/ECs cell sheet

Pangesty

Arahira

Todo

2017

J Mater Sci: Mater Med

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Tissue engineering offers an alternate approach to providing vascular graft with potential to grow similar with native tissue by seeding autologous cells into biodegradable scaffold. In this study, we developed a combining technique by layering a sheet of cells onto a porous tubular scaffold. The cell sheet prepared from co-culturing human mesenchymal stem cells (hMSCs) and endothelial cells (ECs) were able to infiltrate through porous structure of the tubular poly (lactide-co-caprolactone) (PLCL) scaffold and further proliferated on luminal wall within a week of culture. Moreover, the co-culture cell sheet within the tubular scaffold has demonstrated a faster proliferation rate than the monoculture cell sheet composed of MSCs only. We also found that the co-culture cell sheet expressed a strong angiogenic marker, including vascular endothelial growth factor (VEGF) and its receptor (VEGFR), as compared with the monoculture cell sheet within 2 weeks of culture, indicating that the co-culture system could induce differentiation into endothelial cell lineage. This combined technique would provide cellularization and maturation of vascular construct in relatively short period with a strong expression of angiogenic properties.

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Improvement of Mechanical Strength of Tissue Engineering Scaffold Due to the Temperature Control of Polymer Blend Solution

Pangesty

Todo

2021

JFB

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Polymeric scaffolds made of PCL/PLCL (ratio 1:3, respectively) blends have been developed by using the Thermally Induced Phase Separation (TIPS) process. A new additional technique has been introduced in this study by applying pre-heat treatment to the blend solution before the TIPS process. The main objective of this study is to evaluate the influence of the pre-heat treatment on mechanical properties. The mechanical evaluation showed that the mechanical strength of the scaffolds (including tensile strength, elastic modulus, and strain) improved as the temperature of the polymer blend solution increased. The effects on the microstructure features were also observed, such as increasing strut size and differences in phase separation morphology. Those microstructure changes due to temperature control contributed to the increasing of mechanical strength. The in vitro cell study showed that the PCL/PLCL blend scaffold exhibited better cytocompatibility than the neat PCL scaffold, indicated by a higher proliferation at 4 and 7 days in culture. This study highlighted that the improvement of the mechanical strength of polymer blends scaffolds can be achieved using a very versatile way by controlling the temperature of the polymer blend solution before the TIPS process.

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Effect of hydrothermal temperature on phase transformation and mechanical property of non-sintered hydroxyapatite and its in vitro solubility

Sunarso

Rino

Qalbina

et al. 2022

J. Korean Ceram. Soc.

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Characterization of Tensile Mechanical Behavior of MSCs/PLCL Hybrid Layered Sheet

Pangesty

Arahira

Todo

2016

JFB

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A layered construct was developed by combining a porous polymer sheet and a cell sheet as a tissue engineered vascular patch. The primary objective of this study is to investigate the influence of mesenchymal stem cells (MSCs) sheet on the tensile mechanical properties of porous poly-(l-lactide-co-ε-caprolactone) (PLCL) sheet. The porous PLCL sheet was fabricated by the solid-liquid phase separation method and the following freeze-drying method. The MSCs sheet, prepared by the temperature-responsive dish, was then layered on the top of the PLCL sheet and cultured for 2 weeks. During the in vitro study, cellular properties such as cell infiltration, spreading and proliferation were evaluated. Tensile test of the layered construct was performed periodically to characterize the tensile mechanical behavior. The tensile properties were then correlated with the cellular properties to understand the effect of MSCs sheet on the variation of the mechanical behavior during the in vitro study. It was found that MSCs from the cell sheet were able to migrate into the PLCL sheet and actively proliferated into the porous structure then formed a new layer of MSCs on the opposite surface of the PLCL sheet. Mechanical evaluation revealed that the PLCL sheet with MSCs showed enhancement of tensile strength and strain energy density at the first week of culture which is characterized as the effect of MSCs proliferation and its infiltration into the porous structure of the PLCL sheet. New technique was presented to develop tissue engineered patch by combining MSCs sheet and porous PLCL sheet, and it is expected that the layered patch may prolong biomechanical stability when implanted in vivo.

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Development of Ankle-Foot Orthosis with the Integration of IoT Controller

Wahid¹,

Tardan²,

Pangesty³

et al. 2022

IJETAE

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— Immobilisation in bed for an extended period can cause the patient to experience complications such as muscle atrophy and muscle shortness. Ankle foot orthosis, AFO application can assist the bedridden patient in keeping their calf muscle active. However, the existing AFO used for the bedridden patient is fixed. In contrast, another AFO is only used for assisting the patient to walk. Thus, this project aims to design a customized adjustable AFO for the bedridden patient, analyze the strength of the AFO with different parameters, and fabricate using 3D printing technology to integrate remote control. The project begins with the problem identification, concept generation and selection, preliminary design using CAD software, conducting finite element analysis (FEA) by identifying the effect of using different materials, different thicknesses, and different load applies. Finally, the fabrication of AFO used 3D printing technology with PLA materials, and the integration of remote control was installed. Keywords— Bedridden; Bed-resting; Ankle foot orthosis; 3D printing; IoT controller

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