Your search keyword '"Shirazi RN"' showing total 6 results

1. Physical and mechanical degradation behaviour of semi-crystalline PLLA for bioresorbable stent applications.

Author

Polak-Kraśna K, Abaei AR, Shirazi RN, Parle E, Carroll O, Ronan W, and Vaughan TJ

Subjects

Biocompatible Materials, Polymers, Stents, Tensile Strength, Absorbable Implants, Polyesters

Abstract

This study presents a systematic evaluation of the physical, thermal and mechanical performance of medical-grade semi-crystalline PLLA undergoing thermally-accelerated degradation. Samples were immersed in phosphate-buffered saline solution at 50 °C for 112 days and mass loss, molecular weight, thermal properties, degree of crystallinity, FTIR and Raman spectra, tensile elastic modulus, yield stress and failure stress/strain were evaluated at consecutive time points. Samples showed a consistent reduction in molecular weight and melting temperature, a consistent increase in percent crystallinity and limited changes in glass transition temperature and mass loss. At day 49, a drastic reduction in tensile failure strain was observed, despite the fact that elastic modulus, yield and tensile strength of samples were maintained. Brittleness increase was followed by rapid increase in degradation rate. Beyond day 70, samples became too brittle to test indicating substantial deterioration of their load-bearing capacity. This study also presents a computational micromechanics framework that demonstrates that the elastic modulus of a semi-crystalline polymer undergoing degradation can be maintained, despite a reducing molecular weight through compensatory increases in percent crystallinity. This study presents novel insight into the relationship between physical properties and mechanical performance of medical-grade PLLA during degradation and could have important implications for design and development of bioresorbable stents for vascular applications., (Copyright © 2021 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2021

2. Multiscale Experimental and Computational Modeling Approaches to Characterize Therapy Delivery to the Heart from an Implantable Epicardial Biomaterial Reservoir.

Author

Shirazi RN, Islam S, Weafer FM, Whyte W, Varela CE, Villanyi A, Ronan W, McHugh P, and Roche ET

Subjects

Biocompatible Materials chemistry, Computational Biology methods, Pericardium metabolism, Tomography, Emission-Computed, Drug Delivery Systems methods, Myocardium metabolism

Abstract

Delivery of therapeutic-laden biomaterials to the epicardial surface of the heart presents a promising method of treating a variety of diseased conditions by offering targeted, localized release with limited systemic recirculation and enhanced myocardial tissue uptake. A vast range of biomaterials and therapeutic agents using this approach been investigated. However, the fundamental factors that govern transport of the drug molecules from the biomaterials to the tissue are not well understood. Here, the transport of a drug analog from a biomaterial reservoir to the epicardial surface is characterized using experimental techniques and microscale modeling. Using the experimentally determined parameters, a multiscale model of transport is developed. The model is then used to study the effect of important design parameters such as loading conditions, biomaterial geometry, and orientation relative to the cardiac fibers on drug delivery to the myocardium. The simulations highlight the significance of the cardiac fiber anisotropy as a crucial factor in governing drug distribution on the epicardial surface and limiting factor for penetration into the myocardium. The multiscale model can be useful for rapid iteration of different device concepts and for determination of designs for epicardial drug delivery that may be optimal and most promising for the ultimate therapeutic goal., (© 2019 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2019

3. Sustained release of targeted cardiac therapy with a replenishable implanted epicardial reservoir.

Author

Whyte W, Roche ET, Varela CE, Mendez K, Islam S, O'Neill H, Weafer F, Shirazi RN, Weaver JC, Vasilyev NV, McHugh PE, Murphy B, Duffy GP, Walsh CJ, and Mooney DJ

Subjects

Animals, Cells, Cultured, Equipment Design, Female, Myocardial Infarction therapy, Rats, Rats, Sprague-Dawley, Cell- and Tissue-Based Therapy instrumentation, Pericardium physiology, Pericardium surgery, Prostheses and Implants, Regenerative Medicine instrumentation

Abstract

The clinical translation of regenerative therapy for the diseased heart, whether in the form of cells, macromolecules or small molecules, is hampered by several factors: the poor retention and short biological half-life of the therapeutic agent, the adverse side effects from systemic delivery, and difficulties with the administration of multiple doses. Here, we report the development and application of a therapeutic epicardial device that enables sustained and repeated administration of small molecules, macromolecules and cells directly to the epicardium via a polymer-based reservoir connected to a subcutaneous port. In a myocardial infarct rodent model, we show that repeated administration of cells over a four-week period using the epicardial reservoir provided functional benefits in ejection fraction, fractional shortening and stroke work, compared to a single injection of cells and to no treatment. The pre-clinical use of the therapeutic epicardial reservoir as a research model may enable insights into regenerative cardiac therapy, and assist the development of experimental therapies towards clinical use.

Published

2018

4. Effects of material thickness and processing method on poly(lactic-co-glycolic acid) degradation and mechanical performance.

Author

Shirazi RN, Aldabbagh F, Ronan W, Erxleben A, Rochev Y, and McHugh P

Subjects

Absorbable Implants, Biocompatible Materials chemistry, Compressive Strength, Computer Simulation, Crystallization, Diffusion, Elastic Modulus, Hardness, Hydrogen-Ion Concentration, Molecular Weight, Optics and Photonics, Polylactic Acid-Polyglycolic Acid Copolymer, Solvents chemistry, Stress, Mechanical, Surface Properties, X-Ray Diffraction, Lactic Acid chemistry, Materials Testing, Polyglycolic Acid chemistry

Abstract

In this study, the effects of material thickness and processing method on the degradation rate and the changes in the mechanical properties of poly(lactic-co-glycolic acid) material during simulated physiological degradation were investigated. Two types of poly(lactic-co-glycolic acid) materials were considered: 0.12 mm solvent-cast films and 1 mm compression-moulded plates. The experimental results presented in this study were compared to the experimental results of Shirazi et al. (Acta Biomaterialia 10(11):4695-703, 2014) for 0.25 mm solvent-cast films. These experimental observations were used to validate the computational modelling predictions of Shirazi et al. (J Mech Behav Biomed Mater 54: 48-59, 2016) on critical diffusion length scale and also to refine the model parameters. The specific material processing methods considered here did not have a significant effect on the degradation rate and the changes in mechanical properties during degradation; however, they influenced the initial molecular weight and they determined the stiffness and hardness of the poly(lactic-co-glycolic acid) material. The experimental observations strongly supported the computational modelling predictions that showed no significant difference in the degradation rate and the changes in the elastic modulus of poly(lactic-co-glycolic acid) films for thicknesses larger than 100 μm.

Published

2016

5. Modelling the degradation and elastic properties of poly(lactic-co-glycolic acid) films and regular open-cell tissue engineering scaffolds.

Author

Shirazi RN, Ronan W, Rochev Y, and McHugh P

Subjects

Materials Testing, Molecular Conformation, Molecular Weight, Polylactic Acid-Polyglycolic Acid Copolymer, Biocompatible Materials chemistry, Elastic Modulus, Lactic Acid chemistry, Models, Molecular, Polyglycolic Acid chemistry, Tissue Engineering, Tissue Scaffolds chemistry

Abstract

Scaffolding plays a critical rule in tissue engineering and an appropriate degradation rate and sufficient mechanical integrity are required during degradation and healing of tissue. This paper presents a computational investigation of the molecular weight degradation and the mechanical performance of poly(lactic-co-glycolic acid) (PLGA) films and tissue engineering scaffolds. A reaction-diffusion model which predicts the degradation behaviour is coupled with an entropy-based mechanical model which relates Young׳s modulus and the molecular weight. The model parameters are determined based on experimental data for in-vitro degradation of a PLGA film. Microstructural models of three different scaffold architectures are used to investigate the degradation and mechanical behaviour of each scaffold. Although the architecture of the scaffold does not have a significant influence on the degradation rate, it determines the initial stiffness of the scaffold. It is revealed that the size of the scaffold strut controls the degradation rate and the mechanical collapse. A critical length scale due to competition between diffusion of degradation products and autocatalytic degradation is determined to be in the range 2-100μm. Below this range, slower homogenous degradation occurs; however, for larger samples monomers are trapped inside the sample and faster autocatalytic degradation occurs., (Copyright © 2015 Elsevier Ltd. All rights reserved.)

Published

2016

6. Nanomechanical properties of poly(lactic-co-glycolic) acid film during degradation.

Author

Shirazi RN, Aldabbagh F, Erxleben A, Rochev Y, and McHugh P

Subjects

Chromatography, Gel, Elastic Modulus, Hardness, Molecular Weight, Nanoparticles ultrastructure, Polylactic Acid-Polyglycolic Acid Copolymer, Surface Properties, Time Factors, Water chemistry, X-Ray Diffraction, Lactic Acid chemistry, Mechanical Phenomena, Nanoparticles chemistry, Polyglycolic Acid chemistry

Abstract

Despite the potential applications of poly(lactic-co-glycolic) acid (PLGA) coatings in medical devices, the mechanical properties of this material during degradation are poorly understood. In the present work, the nanomechanical properties and degradation of PLGA film were investigated. Hydrolysis of solvent-cast PLGA film was studied in buffer solution at 37 °C. The mass loss, water uptake, molecular weight, crystallinity and surface morphology of the film were tracked during degradation over 20 days. Characterization of the surface hardness and Young's modulus was performed using the nanoindentation technique for different indentation loads. The initially amorphous films were found to remain amorphous during degradation. The molecular weight of the film decreased quickly during the initial days of degradation. Diffusion of water into the film resulted in a reduction in surface hardness during the first few days, followed by an increase that was due to the surface roughness. There was a significant delay between the decrease in the mechanical properties of the film and the decrease in the molecular weight. A sudden decline in mechanical properties indicated that significant bulk degradation had occurred., (Copyright © 2014 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.)

Published

2014