clay and tetrahydrofuran

clay has been researched along with tetrahydrofuran* in 2 studies

Other Studies

2 other study(ies) available for clay and tetrahydrofuran

Article	Year
Manipulation of mechanical compliance of elastomeric PGS by incorporation of halloysite nanotubes for soft tissue engineering applications. Journal of the mechanical behavior of biomedical materials, 2011, Volume: 4, Issue:8 Poly (glycerol sebacate) (PGS) is a promising elastomer for use in soft tissue engineering. However, it is difficult to achieve with PGS a satisfactory balance of mechanical compliance and degradation rate that meet the requirements of soft tissue engineering. In this work, we have synthesised a new PGS nanocomposite system filled with halloysite nanotubes, and mechanical properties, as well as related chemical characters, of the nanocomposites were investigated. It was found that the addition of nanotubular halloysite did not compromise the extensibility of material, compared with the pure PGS counterpart; instead the elongation at rupture was increased from 110 (in the pure PGS) to 225% (in the 20 wt% composite). Second, Young's modulus and resilience of 3-5 wt% composites were ∼0.8 MPa and >94% respectively, remaining close to the level of pure PGS which is desired for applications in soft tissue engineering. Third, an important feature of the 1-5 wt% composites was their stable mechanical properties over an extended period, which could allow the provision of reliable mechanical support to damaged tissues during the lag phase of the healing process. Finally, the in vitro study indicated that the addition of halloysite slowed down the degradation rate of the composites. In conclusion, the good compliance, enhanced stretchability, stable mechanical behavior over an extended period, and reduced degradation rates make the 3-5 wt% composites promising candidates for application in soft tissue engineering. Topics: Aluminum Silicates; Animals; Biocompatible Materials; Cell Death; Clay; Decanoates; Elastomers; Fibroblasts; Furans; Glycerol; Hydrogen-Ion Concentration; Mechanical Phenomena; Mice; Nanotubes; Polymers; Tensile Strength; Tissue Engineering	2011
Preparation of poly(oxybutyleneoxymaleoyl) catalyzed by a proton exchanged montmorillonite clay. Molecules (Basel, Switzerland), 2004, Nov-30, Volume: 9, Issue:11 The polycondensation of tetrahydrofuran with maleic anhydride catalyzed by Maghnite-H+ (Mag-H) was investigated. Maghnite is a montmorillonite sheet silicate clay that is exchanged with protons to produce Maghnite-H [1]. It was found that the polymerization in bulk is initiated by Mag-H in the presence of acetic anhydride at 40 degrees C. The effects of the amounts of Mag-H and acetic anhydride were studied. The polymerization yield increased as the proportions of catalyst and acetic anhydride were increased. Topics: Acetic Anhydrides; Aluminum Silicates; Bentonite; Catalysis; Clay; Furans; Maleic Anhydrides; Molecular Structure; Nuclear Magnetic Resonance, Biomolecular; Polymers; Protons	2004

Article

Year

Manipulation of mechanical compliance of elastomeric PGS by incorporation of halloysite nanotubes for soft tissue engineering applications.

Journal of the mechanical behavior of biomedical materials, 2011, Volume: 4, Issue:8

Poly (glycerol sebacate) (PGS) is a promising elastomer for use in soft tissue engineering. However, it is difficult to achieve with PGS a satisfactory balance of mechanical compliance and degradation rate that meet the requirements of soft tissue engineering. In this work, we have synthesised a new PGS nanocomposite system filled with halloysite nanotubes, and mechanical properties, as well as related chemical characters, of the nanocomposites were investigated. It was found that the addition of nanotubular halloysite did not compromise the extensibility of material, compared with the pure PGS counterpart; instead the elongation at rupture was increased from 110 (in the pure PGS) to 225% (in the 20 wt% composite). Second, Young's modulus and resilience of 3-5 wt% composites were ∼0.8 MPa and >94% respectively, remaining close to the level of pure PGS which is desired for applications in soft tissue engineering. Third, an important feature of the 1-5 wt% composites was their stable mechanical properties over an extended period, which could allow the provision of reliable mechanical support to damaged tissues during the lag phase of the healing process. Finally, the in vitro study indicated that the addition of halloysite slowed down the degradation rate of the composites. In conclusion, the good compliance, enhanced stretchability, stable mechanical behavior over an extended period, and reduced degradation rates make the 3-5 wt% composites promising candidates for application in soft tissue engineering.

Topics: Aluminum Silicates; Animals; Biocompatible Materials; Cell Death; Clay; Decanoates; Elastomers; Fibroblasts; Furans; Glycerol; Hydrogen-Ion Concentration; Mechanical Phenomena; Mice; Nanotubes; Polymers; Tensile Strength; Tissue Engineering

2011

Preparation of poly(oxybutyleneoxymaleoyl) catalyzed by a proton exchanged montmorillonite clay.

Molecules (Basel, Switzerland), 2004, Nov-30, Volume: 9, Issue:11

The polycondensation of tetrahydrofuran with maleic anhydride catalyzed by Maghnite-H+ (Mag-H) was investigated. Maghnite is a montmorillonite sheet silicate clay that is exchanged with protons to produce Maghnite-H [1]. It was found that the polymerization in bulk is initiated by Mag-H in the presence of acetic anhydride at 40 degrees C. The effects of the amounts of Mag-H and acetic anhydride were studied. The polymerization yield increased as the proportions of catalyst and acetic anhydride were increased.

Topics: Acetic Anhydrides; Aluminum Silicates; Bentonite; Catalysis; Clay; Furans; Maleic Anhydrides; Molecular Structure; Nuclear Magnetic Resonance, Biomolecular; Polymers; Protons

2004