Comparative Study of Biocompatible Titanium Alloys Containing Non-Toxic Elements for Orthopedic Implants

Azmat, Ambreen; Asrar, Shafaq; Channa, Iftikhar Ahmed; Ashfaq, Jaweria; Chandio, Irfan Ali; Chandio, Ali Dad; Shar, Muhammad Ali; AlSalhi, Mohamad S.; Devanesan, Sandhanasamy

doi:10.3390/cryst13030467

Cited by 6 publications

(5 citation statements)

References 53 publications

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“…A. Azmat et al (2023) believe that modification of the titanium alloy surface can significantly affect the process and quality of osseointegration. P. Pesode & S. Barve (2021) note that the biological aspect of the interaction of the vitality of the organism's tissue with the non-biological environment depends on the modification of its surface, for example, extending the oxide film's thickness, giving the surface of the material roughness and texture.…”

Section: Discussionmentioning

confidence: 99%

Untitled

2024

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Section: Discussionmentioning

confidence: 99%

Untitled

2024

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“…Examples of β alloys include Ti-6Al-4V, Ti-13Nb-13Zr, and Ti-45Ni, among others. [42][43][44][45] Because of their higher mechanical strength and outstanding biocompatibility, with nontoxic effects and not producing any adverse reactions in biological tissue, β and α-β titanium alloys have found widespread use in biomedical implants in both load-bearing and non-load-bearing joints. Conversely, corrosion of metals other than titanium used in implants, triggered by interactions with body fluids, leads to implant deterioration.…”

Section: Corrosion Behavior Of Biomedical Titanium Alloysmentioning

confidence: 99%

“…Alloys containing β phase are preferable. Examples of β alloys include Ti‐6Al‐4V, Ti‐13Nb‐13Zr, and Ti‐45Ni, among others 42–45 . Because of their higher mechanical strength and outstanding biocompatibility, with nontoxic effects and not producing any adverse reactions in biological tissue, β and α‐β titanium alloys have found widespread use in biomedical implants in both load‐bearing and non‐load‐bearing joints.…”

Section: Corrosion Behavior Of Biomedical Titanium Alloysmentioning

confidence: 99%

Biopolymer‐based coatings for anti‐corrosion of Ti‐alloys used in biomedical applications: A review

Al‐Mosawi,

Abdulsada

2024

Polymer Engineering & Sci

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There are several enviable attributes of titanium and its alloys that contribute to their popularity in biomedical devices and equipment, including their rather low modulus, excellent corrosion resistance, and biocompatibility, good machinability, formability, and strength comprehensive impact and fatigue. Nevertheless, titanium and its alloys do not meet all medical requirements due to its unique properties and alloys, so surface modifications must be made to enhance mechanical, chemical, and biological characteristics. As a review of biomedical engineering, this article discusses specific polymers for coating applications as well as various polymer coatings for functionalization improvements. The versatility of biopolymer coatings makes them extremely appropriate for a broad range of biological uses. To enhance the engineering of tissue and drug delivery, this study summarized and analyzed the most recent advances in biopolymer coatings. Surface qualities of polymer coatings can be adjusted to meet specific criteria for various biomedical applications or integrated with new capabilities. Moreover, polymer coatings containing different inorganic ions can enhance the growth of tissue, proliferation of cells, healing, as well as the transfer of biomolecules, like active molecules, agents of antimicrobial, factors of growth, and medications.Highlights Surface modification avenues of Ti materials as orthopedic replacements are critically reviewed. Basic descriptions of titanium and titanium alloys are presented. Advances in the corrosion behavior of biomedical titanium alloys are thoroughly scrutinized. Fundamental methods based on mechanical, physical, and chemical principles for biopolymer coatings are particularly presented. Main biopolymer coatings types that are used on titanium surfaces are reviewed.

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“…For the material of hip implant, appropriate mechanical properties were considered. Titanium alloy Ti6Al4V was used for the hip implant, and it is known that its characteristics, including being lightweight, strong and biocompatible, are suitable and commonly used in orthopaedic implants [29].…”

Section: Porous Hip Implantmentioning

confidence: 99%

Biomechanical Effects of the Porous Structure of Gyroid and Voronoi Hip Implants: A Finite Element Analysis Using an Experimentally Validated Model

et al. 2023

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Total hip arthroplasty (THA) is most likely one of the most successful surgical procedures in medicine. It is estimated that three in four patients live beyond the first post-operative year, so appropriate surgery is needed to alleviate an otherwise long-standing suboptimal functional level. However, research has shown that during a complete THA procedure, a solid hip implant inserted in the femur can damage the main arterial supply of the cortex and damage the medullary space, leading to cortical bone resorption. Therefore, this study aimed to design a porous hip implant with a focus on providing more space for better osteointegration, improving the medullary revascularisation and blood circulation of patients. Based on a review of the literature, a lightweight implant design was developed by applying topology optimisation and changing the materials of the implant. Gyroid and Voronoi lattice structures and a solid hip implant (as a control) were designed. In total, three designs of hip implants were constructed by using SolidWorks and nTopology software version 2.31. Point loads were applied at the x, y and z-axis to imitate the stance phase condition. The forces represented were x = 320 N, y = −170 N, and z = −2850 N. The materials that were used in this study were titanium alloys. All of the designs were then simulated by using Marc Mentat software version 2020 (MSC Software Corporation, Munich, Germany) via a finite element method. Analysis of the study on topology optimisation demonstrated that the Voronoi lattice structure yielded the lowest von Mises stress and displacement values, at 313.96 MPa and 1.50 mm, respectively, with titanium alloys as the materials. The results also indicate that porous hip implants have the potential to be implemented for hip implant replacement, whereby the mechanical integrity is still preserved. This result will not only help orthopaedic surgeons to justify the design choices, but could also provide new insights for future studies in biomechanics.

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Comparative Study of Biocompatible Titanium Alloys Containing Non-Toxic Elements for Orthopedic Implants

Cited by 6 publications

References 53 publications

Untitled

Untitled

Biopolymer‐based coatings for anti‐corrosion of Ti‐alloys used in biomedical applications: A review

Biomechanical Effects of the Porous Structure of Gyroid and Voronoi Hip Implants: A Finite Element Analysis Using an Experimentally Validated Model

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