A review on innovations in hydroxyapatite: advancing sustainable and multifunctional dental implants.

The increasing relevance of biomaterials in medical curements and the care of aging populations has led to significant advancements in the development and modification of these materials. Hydroxyapatite (HAp), a biocompatible ceramic that mimics the composition of bone mineral, stands out for its remarkable abilities. Its stability in body fluids and ability to integrate with bone without causing toxicity or inflammation made it a prime candidate for biomedical utilization, particularly in odontology and orthopedics. Dental implants, which necessitate a strong interface with the jawbone to effectively support prosthetic devices, are enhanced by coatings of calcium phosphate-based materials like HAp. This enhances osseointegration, ensuring a strong bond and longevity of the implant. HAp may be synthesized both synthetically and from natural sources like mammalian bones, marine shells, and plants, each offering unique trace elements that improve its bioactivity. The synthesis of HAp involves differential technique, including chemical precipitation, and hydrothermal techniques, each impacting the final abilities of the material. The use of natural sources is especially promising, providing a sustainable, cost-effective alternative that retains essential biocompatibility. Hence, this article aims to explore the synthesis, properties, and biomedical applications of hydroxyapatite (HAp), with a special emphasis on its role in improving the performance and durability of dental implants. It also addresses the challenges in manufacturing and biocompatibility, offering insights into future advancements in this field. By addressing current challenges in manufacturing and biocompatibility, HAp paves the way for more effective and long-lasting dental treatments.