Your search keyword '"Eleanor J. Humphrey"' showing total 2 results

1. A flexible polyaniline-based bioelectronic patch

Author

Nastaran Faraji, Lorenzo Travaglini, Antonio Lauto, Joanne Tonkin, Cesare M. Terracciano, Damia Mawad, Jan Seidel, Eleanor J. Humphrey, Chen Cui, David A. Mahns, and J. Justin Gooding

Subjects

Materials science, Phytic Acid, Biomedical Engineering, Biocompatible Materials, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Polymerization, chemistry.chemical_compound, Electricity, Absorbable Implants, Polyaniline, Animals, Rats, Long-Evans, General Materials Science, In situ polymerization, Sheet resistance, chemistry.chemical_classification, Chitosan, Aniline Compounds, Dopant, Polymer, Conductive atomic force microscopy, 021001 nanoscience & nanotechnology, Rats, 0104 chemical sciences, Monomer, chemistry, Chemical engineering, Female, 0210 nano-technology

Abstract

Bioelectronic materials based on conjugated polymers are being developed in the hope to interface with electroresponsive tissues. We have recently demonstrated that a polyaniline chitosan patch can efficiently electro-couple with cardiac tissue modulating its electrophysiology. As a promising bioelectronic material that can be tailored to different types of devices, we investigate here the impact of varying the synthesis conditions and time of the in situ polymerization of aniline (An) on the sheet resistance of the bioelectronic patch. The sheet resistance increases significantly for samples that have either the lowest molar ratio of oxidant to monomer or the highest molar ratio of dopant to monomer, while the polymerization time does not have a significant effect on the electrical properties. Conductive atomic force microscopy reveals that the patch with the lowest sheet resistance has a connected network of the conductive phase. In contrast, patches with higher sheet resistances exhibit conductive areas of lower current signals or isolated conductive islands of high current signals. Having identified the formulation that results in patches with optimal electrical properties, we used it to fabricate patches that were implanted in rats for two weeks. It is shown that the patch retains an electroactive nature, and only mild inflammation is observed with fibrous tissue encapsulating the patch.

Published

2018

2. Poly(3-hydroxyoctanoate), a promising new material for cardiac tissue engineering

Author

Ipsita Roy, Ian C. Locke, Maryam Safari, Prachi Dubey, Aldo R. Boccaccini, Mohan Edirisinghe, Panagiotis Sofokleous, Pooja Basnett, Cesare M. Terracciano, Andrea V. Bagdadi, Sian E. Harding, Eleanor J. Humphrey, and Jonathan C. Knowles

Subjects

0301 basic medicine, chemistry.chemical_classification, Biocompatibility, Biomedical Engineering, Cardiac muscle, Medicine (miscellaneous), 02 engineering and technology, Polymer, 021001 nanoscience & nanotechnology, Polyhydroxyalkanoates, Biomaterials, 03 medical and health sciences, 030104 developmental biology, medicine.anatomical_structure, chemistry, Tissue engineering, medicine, Myocyte, Viability assay, 0210 nano-technology, Cell adhesion, Biomedical engineering

Abstract

Cardiac tissue engineering (CTE) is currently a prime focus of research due to an enormous clinical need. In this work, a novel functional material, Poly(3-hydroxyoctanoate), P(3HO), a medium chain length polyhydroxyalkanoate (PHA), produced using bacterial fermentation, was studied as a new potential material for CTE. Engineered constructs with improved mechanical properties, crucial for supporting the organ during new tissue regeneration, and enhanced surface topography, to allow efficient cell adhesion and proliferation, were fabricated. Our results showed that the mechanical properties of the final patches were close to that of cardiac muscle. Biocompatibility of the P(3HO) neat patches, assessed using Neonatal ventricular rat myocytes (NVRM), showed that the polymer was as good as collagen in terms of cell viability, proliferation and adhesion. Enhanced cell adhesion and proliferation properties were observed when porous and fibrous structures were incorporated to the patches. Also, no deleterious effect was observed on the adults cardiomyocytes’ contraction when cardiomyocytes were seeded on the P(3HO) patches. Hence, P(3HO) based multifunctional cardiac patches are promising constructs for efficient CTE. This work will provide a positive impact on the development of P(3HO) and other PHAs as a novel new family of biodegradable functional materials with huge potential in a range of different biomedical applications, particularly CTE, leading to further interest and exploitation of these materials.

Published

2017