Your search keyword '"Prasopthum A"' showing total 7 results

1. Characterisation of bone regeneration in 3D printed ductile PCL/PEG/hydroxyapatite scaffolds with high ceramic microparticle concentrationsElectronic supplementary information (ESI) available. See DOI: 10.1039/d1bm01645h

Author

Cao, Chuanliang, Huang, Pengren, Prasopthum, Aruna, Parsons, Andrew J., Ai, Fanrong, and Yang, Jing

Abstract

3D printed bioactive glass or bioceramic particle reinforced composite scaffolds for bone tissue engineering currently suffer from low particle concentration (<50 wt%) hence low osteoconductivity. Meanwhile, composites with very high inorganic particle concentrations are very brittle. Scaffolds combining high particle content and ductility are urgently required for bone tissue engineering. Herein, 3D printed PCL/hydroxyapatite (HA) scaffolds with high ceramic concentration (up to 90 wt%) are made ductile (>100% breaking strain) by adding poly(ethylene glycol) which is biocompatible and FDA approved. The scaffolds require no post-printing washing to remove hazardous components. More exposure of HA microparticles on strut surfaces is enabled by incorporating higher HA concentrations. Compared to scaffolds with 72 wt% HA, scaffolds with higher HA content (90 wt%) enhance matrix formation but not new bone volume after 12 weeks implantation in rat calvarial defects. Histological analyses demonstrate that bone regeneration within the 3D printed scaffolds is viaintramembranous ossification and starts in the central region of pores. Fibrous tissue that resembles non-union tissue within bone fractures is formed within pores that do not have new bone. The amount of blood vessels is similar between scaffolds with mainly fibrous tissue and those with more bone tissue, suggesting vascularization is not a deciding factor for determining the type of tissues regenerated within the pores of 3D printed scaffolds. Multinucleated immune cells are commonly present in all scaffolds surrounding the struts, suggesting a role of managing inflammation in bone regeneration within 3D printed scaffolds.

Published

2021

2. Three dimensional printed degradable and conductive polymer scaffolds promote chondrogenic differentiation of chondroprogenitor cells

Author

Prasopthum, Aruna, Deng, Zexing, Khan, Ilyas M., Yin, Zhanhai, Guo, Baolin, and Yang, Jing

Abstract

Conductive polymers have been used for various biomedical applications including biosensors, tissue engineering and regenerative medicine. However, the poor processability and brittleness of these polymers hinder the fabrication of three-dimensional structures with desirable geometries. Moreover, their application in tissue engineering and regenerative medicine has been so far limited to excitable cells such as neurons and muscle cells. To enable their wider adoption in tissue engineering and regenerative medicine, new materials and formulations that overcome current limitations are required. Herein, a biodegradable conductive block copolymer, tetraaniline-b-polycaprolactone-b-tetraaniline (TPT), is synthesised and 3D printed for the first time into porous scaffolds with defined geometries. Inks are formulated by combining TPT with PCL in solutions which are then directly 3D printed to generate porous scaffolds. TPT and PCL are both biodegradable. The combination of TPT with PCL increases the flexibility of the hybrid material compared to pure TPT, which is critical for applications that need mechanical robustness of the scaffolds. The highest TPT content shows the lowest tensile failure strain. Moreover, the absorption of a cell adhesion-promoting protein (fibronectin) and chondrogenic differentiation of chondroprogenitor cells are found to be dependent on the amount of TPT in the blends. Higher content of TPT in the blends increases both fibronectin adsorption and chondrogenic differentiation, though the highest concentration of TPT in the blends is limited by its solubility in the ink. Despite the contradicting effects of TPT concentration on flexibility and chondrogenic differentiation, a concentration that strikes a balance between the two factors is still available. It is worth noting that the effect on chondrogenic differentiation is found in scaffolds without external electric stimulation. Our work demonstrates the possibility of 3D printing flexible conductive and biodegradable scaffolds and their potential use in cartilage tissue regeneration, and opens up future opportunities in using electric stimulation to control chondrogenesis in these scaffolds.

Published

2020

3. Three-Dimensional Printed Scaffolds with Controlled Micro-/Nanoporous Surface Topography Direct Chondrogenic and Osteogenic Differentiation of Mesenchymal Stem Cells

Author

Prasopthum, Aruna, Cooper, Mick, Shakesheff, Kevin M., and Yang, Jing

Abstract

The effect of topography in three-dimensional (3D) printed polymer scaffolds on stem cell differentiation is a significantly underexplored area. Compared to two-dimensional (2D) biomaterials on which various well-defined topographies have been incorporated and shown to direct a range of cell behaviors including adhesion, cytoskeleton organization, and differentiation, incorporating topographical features to 3D polymer scaffolds is challenging due to the difficulty of accessing the inside of a porous scaffold. Only the roughened strut surface has been introduced to 3D printed porous scaffolds. Here, a rapid, single-step 3D printing method to fabricate polymeric scaffolds consisting of microstruts (ca. 60 μm) with micro-/nanosurface pores (0.2–2.4 μm) has been developed based on direct ink writing of an agitated viscous polymer solution. The density, size, and alignment of these pores can be controlled by changing the degree of agitation or the speed of printing. Three-dimensional printed scaffolds with micro-/nanoporous struts enhanced chondrogenic and osteogenic differentiation of mesenchymal stem cells (MSCs) without soluble differentiation factors. The topography also selectively affected adhesion, morphology, and differentiation of MSC to chondrogenic and osteogenic lineages depending on the composition of the differentiation medium. This fabrication method can potentially be used for a wide range of polymers where desirable architecture and topography are required.

Published

2019

4. Spatially-offset Raman spectroscopy for monitoring mineralization of bone tissue engineering scaffolds: feasibility study based on phantom samples

Author

Dooley, Max, Prasopthum, Aruna, Liao, Zhiyu, Sinjab, Faris, McLaren, Jane, Rose, Felicity R. A. J., Yang, Jing, and Notingher, Ioan

Abstract

Using phantom samples, we investigated the feasibility of spatially-offset Raman spectroscopy (SORS) as a tool for monitoring non-invasively the mineralization of bone tissue engineering scaffold in-vivo. The phantom samples consisted of 3D-printed scaffolds of poly-caprolactone (PCL) and hydroxyapatite (HA) blends, with varying concentrations of HA, to mimic the mineralisation process. The scaffolds were covered by a 4 mm layer of skin to simulate the real in-vivo measurement conditions. At a concentration of HA approximately 1/3 that of bone (~0.6 g/cm^3), the characteristic Raman band of HA (960 cm^−1) was detectable when the PCL:HA layer was located at 4 mm depth within the scaffold (i.e. 8 mm below the skin surface). For the layers of the PCL:HA immediately under the skin (i.e. top of the scaffold), the detection limit of HA was 0.18 g/cm^3, which is approximately one order of magnitude lower than that of bone. Similar results were also found for the phantoms simulating uniform and inward gradual mineralisation of the scaffold, indicating the suitability of SORS to detect early stages of mineralisation. Nevertheless, the results also show that the contribution of the materials surrounding the scaffold can be significant and methods for subtraction need to be investigated in the future. In conclusion, these results indicate that spatially-offset Raman spectroscopy is a promising technique for in-vivo longitudinal monitoring scaffold mineralization and bone re-growth.

Published

2019

5. Structure-Function Relationships of Phytochemicals in Control of Mosquito Vectors

Author

Rongnoparut, Pornpimol, Duangkaew, Panida, Prasopthum, Aruna, and Pouyfung, Phisit

Abstract

Mosquito-borne diseases, transmitted by mosquito vectors, continue to cause illness and death in many areas of the world, especially in tropical and subtropical countries. One of the control measures of these diseases has been contingent on mosquito vector control using synthetic chemical insecticides. Due to environmental health concerns of synthetic insecticides and the rise of resistance to synthetic insecticides in mosquitoes, eco-friendly and easily biodegradable natural plant compounds that are potential insecticides are imperative for mosquito vector control and management. Over past decades, searches for insecticidal phytochemicals against mosquitoes have provided a wealth of bioactive insecticidal compounds with various types of chemical structures. This paper provides an overview of compounds from plant sources that are grouped into chemical structural groups containing potential mosquitocidal activities. Each of these groups comprises individual core structure together with large numbers of derivatives. Relationships of chemical structures and toxicities of each compound group and derivatives are highlighted. Natural plant products conferring synergistic activities on cell-based assays with pyrethroid toxicity in relation to their chemical structures are described. Understanding of relationships of bioactive compounds of plant origin belonging to different classes of chemical structures and their activities could be beneficial for effective mosquito vector control measures.

Published

2016

6. Inhibition effects of Vernonia cinereaactive compounds against cytochrome P450 2A6 and human monoamine oxidases, possible targets for reduction of tobacco dependence

Author

Prasopthum, Aruna, Pouyfung, Phisit, Sarapusit, Songklod, Srisook, Ekaruth, and Rongnoparut, Pornpimol

Abstract

The human cytochrome P450 2A6 (CYP2A6) and monoamine oxidases (MAO-A and MAO-B), catalyzing nicotine and dopamine metabolisms, respectively, are two therapeutic targets of nicotine dependence. Vernonia cinerea, a medicinal plant commonly used for treatment of diseases such as asthma and bronchitis, has been shown reducing tobacco dependence effect among tobacco users. In the present study, we found eight active compounds isolated from V. cinereathat comprise inhibitory activity toward CYP2A6 and MAO-A and MAO-B enzymes using activity-guided assays, with coumarin as substrate of CYP2A6 and kynuramine of MAOs. These compounds were three flavones (apigenin, chrysoeriol, luteolin), one flavonol (quercetin), and four hirsutinolide-type sesquiterpene lactones (8α-(2-methylacryloyloxy)-hirsutinolide-13-O-acetate, 8α-(4-hydroxymethacryloyloxy)-hirsutinolide-13-O-acetate, 8α-tigloyloxyhirsutinolide-13-O-acetate, and 8α-(4-hydroxytigloyloxy)-hirsutinolide-13-O-acetate). Modes and kinetics of inhibition against the three enzymes were determined. Flavonoids possessed strong inhibitory effect on CYP2A6 in reversible mode, while inhibition by hirsutinolides was mechanism-based (NADPH-, concentration-, and time-dependence) and irreversible. Inhibition by hirsutinolides could not be reversed by dialysis and by addition of trapping agents or potassium ferricyanide. Flavonoids inhibited MAOs with variable degrees and were more prominent in inhibition toward MAO-A than hirsutinolides, while two of hirsutinolides inhibited MAO-B approximately comparable to two flavonoids. These results could have implications in combination of drug therapy for smoking cessation.

Published

2015

7. Mechanism-based Inactivation of Cytochrome P450 2A6 and 2A13 by Rhinacanthus nasutusConstituents

Author

Pouyfung, Phisit, Prasopthum, Aruna, Sarapusit, Songklod, Srisook, Ekaruth, and Rongnoparut, Pornpimol

Abstract

Human cytochrome P450 CYP2A6 and CYP2A13 catalyze nicotine metabolisms and mediate activation of tobacco-specific carcinogens including 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) and 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanol (NNAL). In this study, we found rhinacanthins A, B, and C isolated from Rhinacanthus nasutuspotentially inhibited coumarin 7-hydroxylation mediated by reconstituted purified recombinant CYP2A6 and CYP2A13. Rhinacanthins A-C are mechanism-based inactivators of CYP2A6 and CYP2A13 as they cause concentration, time and NADPH-dependent inhibition. Among the three rhinacanthins, rhinacanthin-B possessed highest inhibitory potency against CYP2A13 with apparent K and fcinactof 0.16 μΜ and 0.1min−1, respectively, while values of 0.44 μΜ and 0.12min−1were found against CYP2A6. Rhinacanthin-C had least inhibition potency, with apparent K1and kinactof 0.97 μΜ and 0.07min−1for CYP2A6, respectively, and values of 1.68μΜ and 0.05min−1for CYP2A13. Rhinacanthin-A inhibited CYP2A6 and CYP2A13 with apparent K1values of 0.69 and 0.42 μΜ, respectively and apparent kinactof 0.18 and 0.06min−1, respectively. The inhibition of both enzymes by rhinacanthins A-C could not be prevented by addition of trapping agents or reversed by dialysis or potassium ferricyanide. These findings demonstrated that rhinacanthins A-C, which are 1,4-naphthoquinone derivatives, irreversibly inhibited CYP2A6 and CYP2A13 in a mechanism-based inhibition mode.

Published

2014