Your search keyword '"Naguib HE"' showing total 2 results

1. Bio-inspired conductive adhesive based on calcium-free alginate hydrogels for bioelectronic interfaces.

Author

Perkucin I, Lau KSK, Morshead CM, and Naguib HE

Subjects

Animals, Hydrogels chemistry, Adhesives chemistry, Proteins chemistry, Polymers chemistry, Dihydroxyphenylalanine chemistry, Neural Stem Cells, Bivalvia

Abstract

Electrode impedance is one of the greatest challenges facing neural interfacing medical devices and the use of electrical stimulation-based therapies in the fields of neurology and regenerative medicine. Maximizing contact between electronics and tissue would allow for more accurate recordings of neural activity and to stimulate with less power in implantable devices as electric signals could be more precisely transferred by a stable interfacial area. Neural environments, inherently wet and ion-rich, present a unique challenge for traditional conductive adhesives. As such, we look to marine mussels that use a 3,4-dihydroxyphenyl-L-analine (DOPA)-containing proteinaceous excretion to adhere to a variety of substrates for inspiration. By functionalizing alginate, which is an abundantly available natural polymer, with the catechol residues DOPA contains, we developed a hydrogel-based matrix to which carbon-based nanofiller was added to render it conductive. The synthesized product had adhesive energy within the range of previously reported mussel-based polymers, good electrical properties and was not cytotoxic to brain derived neural precursor cells., (Creative Commons Attribution license.)

Published

2022

2. Standardized static and dynamic evaluation of myocardial tissue properties.

Author

Ramadan S, Paul N, and Naguib HE

Subjects

Animals, Biomechanical Phenomena, Elastic Modulus, Heart anatomy & histology, Materials Testing, Sheep, Swine, Tensile Strength, Tissue Engineering, Viscosity, Heart physiology

Abstract

Introduction: Quantifying the mechanical behaviors of soft biological tissues is of considerable research interest. However, validity and reproducibility between different researchers and apparatus is questionable. This study aims to quantify the mechanical properties of myocardium while investigating methodologies that can standardize biological tissue testing., Materials and Methods: Tensile testing was performed to obtain Young's modulus and a dynamic mechanical analysis (DMA) determined the viscoelastic properties. A frequency range of 0.5 Hz (30bpm) to 3.5 Hz (210bpm) was analyzed. For tensile testing three different preconditioning settings were tested: no load, 0.05 N preload, and a cyclic preload at 2.5% strain and 10 cycles. Samples were placed in saline and tested at 37 °C. Five ovine and five porcine hearts were tested., Results and Discussion: Cyclic loading results in the most consistent moduli values. The modulus of ovine/porcine tissue was mean = 0.05/.06 MPa, SD = 0.02/0.03 MPa. The storage/loss modulus varied from = 0.02/0.003 MPa at 0.5 Hz to 0.04/0.008 MPa at 3.5 Hz; Stiffness increases linearly from 400 to 800 N m -1 with a tan delta around 0.175., Conclusions: Static analysis of the mechanical properties of myocardial tissue confirms that; preconditioning is necessary for reproducibility, and DMA provides a platform for reproducible testing of soft biological tissues.

Published

2017