Your search keyword '"Ammar Alsheghri"' showing total 2 results

1. High strength brushite bioceramics obtained by selective regulation of crystal growth with chiral biomolecules

Author

Haihua Pan, Ruikang Tang, Wenge Jiang, Javier Vargas, Jun Song, Ammar Alsheghri, Marc D. McKee, Alaa Mansour, Amir El Hadad, Faleh Tamimi, and Hanan Moussa

Subjects

Calcium Phosphates, Ceramics, Materials science, Compressive Strength, 0206 medical engineering, Biomedical Engineering, 02 engineering and technology, Crystal structure, Molecular Dynamics Simulation, Biochemistry, law.invention, Biomaterials, Crystal, law, Materials Testing, Brushite, Crystallization, Tartrates, Molecular Biology, chemistry.chemical_classification, Biomolecule, Stereoisomerism, General Medicine, 021001 nanoscience & nanotechnology, 020601 biomedical engineering, Compressive strength, chemistry, Chemical engineering, 0210 nano-technology, Chirality (chemistry), Biotechnology, Biomineralization

Abstract

Chirality seems to play a key role in mineralization. Indeed, in biominerals, the biomolecules that guide the formation and organization of inorganic crystals and help construct materials with exceptional mechanical properties, are homochiral. Here, we show that addition of homochiral l -(+)-tartaric acid improved the mechanical properties of brushite bioceramics by decreasing their crystal size, following the classic Hall-Petch strengthening effect; d -(-)-tartaric acid had the opposite effect. Adding l -(+)-Tar increased both the compressive strength (26 MPa) and the fracture toughness (0.3 MPa m1/2) of brushite bioceramics, by 33% and 62%, respectively, compared to brushite bioceramics without additives. In addition, l -(+)-tartaric acid enabled the fabrication of cements with high powder-to-liquid ratios, reaching a compressive strength and fracture toughness as high as 32.2 MPa and 0.6 MPa m1/2, respectively, approximately 62% and 268% higher than that of brushite bioceramics prepared without additives, respectively. Characterization of brushite crystals from the macro- to the atomic-level revealed that this regulation is attributable to a stereochemical matching between l -(+)-tartaric acid and the chiral steps of brushite crystals, which results in inhibition of brushite crystallization. These findings provide insight into understanding the role of chirality in mineralization, and how to control the crystallographic structure of bioceramics to achieve high-performance mechanical properties. Statement of Significance Calcium-phosphate cements are promising bone repair materials. However, their suboptimal mechanical properties limit their clinical use. Natural biominerals have remarkable mechanical properties that are the result of controlled size, shape and organization of their inorganic crystals. This is achieved by biomineralization proteins that are homochiral, composed of l - amino acids. Despite the importance of chiral l -biomolecules in biominerals, using homochiral molecules to fabricate bone cements has not been studied yet. In this study, we showed that homochiral l -(+)-tartaric acid can regulate the crystal structure and improve the mechanical properties of a calcium-phosphate cement. Hence, these findings open the door for a new way of designing strong bone cement and highlight the importance of chirality in bioceramics.

Published

2020

2. Bio-inspired and optimized interlocking features for strengthening metal/polymer interfaces in additively manufactured prostheses

Author

Binhan Sun, Jun Song, Mohamed A. Mezour, Omar Alageel, Stephen Yue, Faleh Tamimi, and Ammar Alsheghri

Subjects

Toughness, Materials science, Polymers, Finite Element Analysis, Biomedical Engineering, 02 engineering and technology, Biochemistry, Biomaterials, Stress (mechanics), 03 medical and health sciences, 0302 clinical medicine, Biomimetics, Ultimate tensile strength, medicine, Polymethyl Methacrylate, Displacement (orthopedic surgery), Composite material, Molecular Biology, Interlocking, chemistry.chemical_classification, Stiffness, 030206 dentistry, General Medicine, Polymer, Prostheses and Implants, 021001 nanoscience & nanotechnology, Finite element method, chemistry, Metals, Stress, Mechanical, medicine.symptom, 0210 nano-technology, Biotechnology

Abstract

Biomedical and dental prostheses combining polymers with metals often suffer failure at the interface. The weak chemical bond between these two dissimilar materials can cause debonding and mechanical failure. This manuscript introduces a new mechanical interlocking technique to strengthen metal/polymer interfaces through optimized additively manufactured features on the metal surface. To reach an optimized design of interlocking features, we started with the bio-mimetic stress-induced material transformation (SMT) optimization method. The considered polymer and metal materials were cold-cured Poly(methyl methacrylate) (PMMA) and laser-sintered Cobalt-Chromium (Co-Cr), respectively. Optimal dimensions of the bio-inspired interlocking features were then determined by mesh adaptive direct search (MADS) algorithm combined with finite element analysis (FEA) and tensile experiments such that they provide the maximum interfacial tensile strength and stiffness while minimizing the stress in PMMA and the displacement of PMMA at the Co-Cr/PMMA interface. The SMT optimization process suggested a Y-shape as a more favorable design, which was similar to mangrove tree roots. Experiments confirmed that our optimized interlocking features increased the strength of the Co-Cr/PMMA interface from 2.3 MPa (flat interface) to 34.4 ± 1 MPa, which constitutes 85% of the tensile failure strength of PMMA (40.2 ± 1 MPa). Statement of Significance The objective of this study was to improve metal/polymer interfacial strength in dental and orthopedic prostheses. This was achieved by additive manufacturing of optimized interlocking features on metallic surfaces using laser-sintering. The interlocking design of the features, which was a Y-shape similar to the roots of mangrove trees, was inspired by a bio-memetic optimization algorithm. This interlocking design lowered the PMMA displacement at the Co-Cr/PMMA interface by 70%, enhanced the interfacial strength by more than 12%, and increased the stiffness by 18% compared with a conventional bead design, meanwhile no significant difference was found in the toughness of both designs.

Published

2018