Blends of High Molecular Weight Poly(lactic acid) (PLA) with Copolymers of 2-bromo-3-hydroxypropionic Acid And Lactic Acid (PLB)

Lei, Xia

07 June 2013

No description available.

Polymers

Miscibility

Poly(lactic acid)

Production of Poly(lactic acid) Biodegradable Films and the Introduction of a Novel Initiation Method for Free Radical Polymerization via Magnetic Fields

Miller, Kent R.

19 July 2012

No description available.

Engineering

Polymers

poly(lactic acid)

biodegradable film

magnetic macro-initiator

magnetic initiation

free radical polymerization

Structure and blood compatibility of highly oriented poly(lactic acid)/thermoplastic polyurethane blends produced by solid hot stretching

Zhao, X., Ye, L., Coates, Philip D., Caton-Rose, Philip D.

12 May 2013

Yes / Highly oriented poly(lactic acid) (PLA)/thermoplastic polyurethane (TPU) blends were fabricated through solid hot stretching technology in an effort to improve the mechanical properties and blood biocompatibility of PLA as blood-contacting medical devices. It was found that the tensile strength and modulus of the blends can be improved dramatically by stretching. With the increase of draw ratio, the cold crystallization peak became smaller, and the glass transition and the melting peak moved to high temperature, while the crystallinity increased, and the grain size of PLA decreased, indicating of the stress-induced crystallization during drawing. The oriented blends exhibited structures with longitudinal striations which indicate the presence of micro-fibers. TPU phase was finely and homogeneously dispersed in the PLA, and after drawing, TPU domains were elongated to ellipsoid. The introduction of TPU and orientation could enhance the blood compatibility of PLA by prolonging kinetic clotting time, and decreasing hemolysis ratio and platelet activation.

Poly(lactic acid) (PLA)

Thermoplastic polyurethane (TPU)

Solid hot stretching

Orientation

Mechanical properties

Blood compatibility

Fibrillation of chain branched poly (lactic acid) with improved blood compatibility and bionic structure

Li, Z., Zhao, X., Ye, L., Coates, Philip D., Caton-Rose, Philip D., Martyn, Michael T.

25 May 2015

Yes / Highly-oriented poly (lactic acid) (PLA) with bionic fibrillar structure and micro-grooves was fabricated through solid hot drawing technology for further improving the mechanical properties and blood biocompatibility of PLA as blood-contacting medical devices. In order to enhance the melt strength and thus obtain high orientation degree, PLA was first chain branched with pentaerythritol polyglycidyl ether (PGE). The branching degree as high as 12.69 mol% can be obtained at 0.5 wt% PGE content. The complex viscosity, elastic and viscous modulus for chain branched PLA were improved resulting from the enhancement of molecular entanglement, and consequently higher draw ratio can be achieved during the subsequent hot stretching. The stress-induced crystallization of PLA occurred during stretching, and the crystal structure of the oriented PLA can be attributed to the α′ crystalline form. The tensile strength and modulus of PLA were improved dramatically by drawing. Chain branching and orientation could significantly enhance the blood compatibility of PLA by prolonging clotting time and decreasing hemolysis ratio, protein adsorption and platelet activation. Fibrous structure as well as micro-grooves can be observed for the oriented PLA which were similar to intimal layer of blood vessel, and this bionic structure was considered to be beneficial to decrease the activation and/or adhesion of platelets.

Poly (lactic acid) (PLA)

Chain branching

Fibrillation

Mechanical properties

Blood compatibility

Bionic character

High orientation of long chain branched poly (lactic acid) with enhanced blood compatibility and bionic structure

Li, Z., Ye, L., Zhao, X., Coates, Philip D., Caton-Rose, Philip D., Martyn, Michael T.

20 January 2016

Yes / Highly-oriented poly (lactic acid) (PLA) with bionic micro-grooves was fabricated through solid hot drawing technology for further improving the mechanical properties and blood biocompatibility of PLA. In order to enhance the melt strength and thus obtain high orientation degree, long chain branched PLA (LCB-PLA) was prepared at first through a two-step ring-opening reaction during processing. Linear viscoelasticity combined with branch-on-branch (BOB) model was used to predict probable compositions and chain topologies of the products, and it was found that the molecular weight of PLA increased and topological structures with star like chain with three arms and tree-like chain with two generations formed during reactive processing, and consequently draw ratio as high as1200% can be achieved during the subsequent hot stretching. With the increase of draw ratio, the tensile strength and orientation degree of PLA increased dramatically. Long chain branching and orientation could significantly enhance the blood compatibility of PLA by prolonging clotting time and decreasing platelet activation. Micro-grooves can be observed on the surface of the oriented PLA which were similar to the intimal layer of blood vessel, and such bionic structure resulted from the formation of the oriented shish kebab-like crystals along the draw direction.

Poly (lactic acid) (PLA)

Long chain branching

Mechanical properties

Blood compatibility

Bionic character

Structure and blood compatibility of highly oriented PLA/MWNTs composites produced by solid hot drawing

Li, Z., Zhao, X., Ye, L., Coates, Philip D., Caton-Rose, Philip D., Martyn, Michael T.

January 2013

Yes / Highly oriented poly(lactic acid) (PLA)/multi-walled carbon nanotubes (MWNTs) composites were fabricated through solid hot drawing technology in an effort to improve the mechanical properties and blood biocompatibility of PLA as blood-contacting medical devices. It was found that proper MWNTs content and drawing orientation can improve the tensile strength and modulus of PLA dramatically. With the increase in draw ratio, the cold crystallization peak became smaller, and the glass transition and the melting peak of PLA moved to high temperature, while the crystallinity increased, and the grain size decreased, indicating the stress-induced crystallization of PLA during drawing. MWNTs showed a nucleation effect on PLA, leading to the rise in the melting temperature, increase in crystallinity and reduction of spherulite size for the composites. Moreover, the intensity of (002) diffraction of MWNTs increased with draw ratio, indicating that MWNTs were preferentially aligned and oriented during drawing. Microstructure observation demonstrated that PLA matrix had an ordered fibrillar bundle structure, and MWNTs in the composite tended to align parallel to the drawing direction. In addition, the dispersion of MWNTs in PLA was also improved by orientation. Introduction of MWNTs and drawing orientation could significantly enhance the blood compatibility of PLA by prolonging kinetic clotting time, reducing hemolysis ratio and platelet activation.

Poly (lactic acid)

Multi-walled carbon nanotubes

Composites

Solid hot drawing

Orientation

Mechanical properties

Blood compatibility

Fabrication of Poly-Lactic Acid (PLA) Composite Films and Their Degradation Properties

Guan, Xin

09 July 2012

No description available.

Agricultural Engineering

Biomechanics

Poly-lactic Acid

Tensile strength

SEM

TGA

Starch

Cellulose

Methyl cellulose.

Influence of Additives on the Foamability of Potato Starch based Biopolymers

Oza, Hiteshkumar G.

10 1900

<p>In this study, attempts were made to diversify the application of potato starch based biopolymer as foam-grade materials. To improve foamability, which is largely dependent on melt strength, it is possible to modify hydrolyzed starch based biopolymers by bulk modification with bi- and multi- functional epoxy chain extenders. The modification work was carried out using a twin screw extruder (TSE) and an internal batch mixer (Haake Mixer) with four different chain extenders. The modified blends were characterized by Parallel Plate Rheometry, DSC, Intrinsic Viscosity and SEM techniques. Finally, foamability of the modified blends was examined by using supercritical CO₂ as a physical blowing agent in a high-pressure batch vessel. Variables such as saturation pressure, saturation time and saturation temperature were adjusted to determine their influence on the cell morphology of the foamed parts.</p> <p>The multi-functional epoxy chain extenders effectively increased the bulk melt viscosity and reduced the crystalline content of both hydrolyzed starch based biopolymers. The intrinsic viscosity measurements were quantified the chain extension reaction, which primarily occurred in the PLA/AAC or PLA phase in both biopolymers and the starch phase made no contribution towards increased bulk melt viscosity. The multi-functional Joncryl^® ADR 4370S was the most effective chain extender for improving the stability of foams by yielding smaller cell size and higher cell density in comparison with the original biopolymer during the batch foaming process at 10 MPa saturation pressure and 30 min saturation time. The use of other chain extenders proved to be mostly ineffectual in producing uniform cellular structure in their corresponding modified biopolymer at those same processing conditions.</p> / Master of Applied Science (MASc)

Hydrolyzed Starch

Poly (lactic acid)

Chian Extender. Batch Foaming

Polymer Science

Polymer Science

Enhancing poly(lactic acid) microcellular foams by formation of distinctive crystalline structures

Li, R., Ye, L., Zhao, X., Coates, Philip D., Caton-Rose, Philip D.

13 January 2021

Yes / By controlling the crystallization behavior of poly(lactic acid) (PLA) in the presence of a hydrazide nucleating agent (HNA), PLA-HNA foams with enhanced microcellular structures were prepared via supercritical CO2 foaming. It was found that HNA can self-assemble into fibrillar networks, inducing the crystallization of PLA on their surface, and "shish-kebab"crystalline structures with high crystallinity formed, which can be maintained during the whole foaming process. Incorporation of HNA promoted the formation of gt conformers, improved the amount of dissolved CO2, hindered the escape of CO2, and increased the viscoelasticity of PLA. Compared with neat PLA foam, for PLA-HNA foam, the average cell diameter decreased obviously, from 64.39 to 6.59 μm, while the cell density increased up to nearly three orders of magnitudes, from 6.82 × 106 to 4.44 × 109 cells/cm3. Moreover, lots of fibrillar structures appeared and entangled with each other on the cell wall of the foam. By forming such dense micropores and enhanced fibrillar structures, PLA foam was highly reinforced with significantly improved compressive strength. / This research was financially supported by National Natural Science Foundation of China (grant no. 51773122) and State Key Laboratory of Polymer Materials Engineering (grant no. sklpme2019-2-21).

Poly(lactic acid) (PLA)

Microcellular foam

Enhanced crystalline structure

Foaming behaviour

Reinforcing mechanism

Improved Properties of Poly (Lactic Acid) with Incorporation of Carbon Hybrid Nanostructure

Kim, Junseok

01 July 2016

Poly(lactic acid) is biodegradable polymer derived from renewable resources and non-toxic, which has become most interested polymer to substitute petroleum-based polymer. However, it has low glass transition temperature and poor gas barrier properties to restrict the application on hot contents packaging and long-term food packaging. The objectives of this research are: (a) to reduce coagulation of graphene oxide/single-walled carbon nanotube (GOCNT) nanocomposite in poly(lactic acid) matrix and (b) to improve mechanical strength and oxygen barrier property, which extend the application of poly(lactic acid). Graphene oxide has been found to have relatively even dispersion in poly(lactic acid) matrix while its own coagulation has become significant draw back for properties of nanocomposite such as gas barrier, mechanical properties and thermo stability as well as crystallinity. Here, single-walled carbon nanotube was hybrid with graphene oxide to reduce irreversible coagulation by preventing van der Waals of graphene oxide. Mass ratio of graphene oxide and carbon nanotube was determined as 3:1 at presenting greatest performance of preventing coagulation. Four different weight percentage of GOCNT nanocomposite, which are 0.05, 0.2, 0.3 and 0.4 weight percent, were composited with poly(lactic acid) by solution blending method. FESEM morphology determined minor coagulation of GOCNT nanocomopsite for different weight percentage composites. Insignificant crystallinity change was observed in DSC and XRD data. At 0.4 weight percent, it prevented most of UV-B light but was least transparent. GOCNT nanocomposite weight percent was linearly related to ultimate tensile strength of nanocomposite film. The greatest ultimate tensile strength was found at 0.4 weight percent which is 175% stronger than neat poly(lactic acid) film. Oxygen barrier property was improved as GOCNT weight percent increased. 66.57% of oxygen transmission rate was reduced at 0.4 weight percent compared to neat poly(lactic acid). The enhanced oxygen barrier property was ascribed to the outstanding impermeability of hybrid structure GOCNT as well as the strong interfacial adhesion of GOCNT and poly(lactic acid) rather than change of crystallinity. Such a small amount of GOCNT nanocomposite improved mechanical strength and oxygen barrier property while there were no significant change of crystallinity and thermal behavior found. / Master of Science

poly(lactic acid)

graphene oxide

single-walled carbon nanotube

coagulation

mechanical property

crystalline

oxygen barrier property