Exploring what gives titanium implants their remarkable biocompatibility

Band gap energies of the passive film on Ti are relatively small. That is one factor generating the excellent biocompatibility. Credit: Department of Metallic Biomaterials,TMDU

Scientists from the Tokyo Medical and Dental University (TMDU) used photoelectrochemical measurement and X-ray photoelectron spectroscopy to clarify the source of titanium’s biocompatibility when implanted into the body, as with hip replacements and dental implants. They find that its reactivity with the correct ions in the extracellular fluid allows the body to recognize it. This work may lead to new generation medical implants that last longer.

Owing to its excellent strength and resistance to corrosion, titanium is commonly used in medical and dental implants. Over time, doctors have also noticed that patients with titanium implants generate less of an immune response than normally occurs when a foreign material is placed inside the body. This has been explained based on the biocompatibility of titanium. This biocompatibility may generate a problem, such as when screws made from titanium alloys assimilate too much into bone tissue after long-term implantation, which makes them difficult to remove later. Despite numerous studies on biological reactions with implanted materials, the reason for the biocompatibility of titanium remains poorly understood. A more complete explanation of the surface properties that give titanium these features is needed.

Now, a team of researchers led by TMDU has tested thin disks of titanium in a solution containing ions meant to mimic the extracellular fluid of the body, as well as in saline. They measured how much photoelectrical current was generated when light of various wavelengths was illuminated on the disks. They also performed X-ray photoelectron spectroscopy to characterize the passive films that were naturally present on the surface of the titanium.

“Passive films consisted of a very thin TiO2 layer containing small amounts of Ti2O3 and TiO, hydroxyl groups, and water. During polarization in Hanks, calcium and phosphate ions were incorporated or formed calcium phosphate but not in saline,” says first author Seong-Cheol Kim. Calcium phosphate also formed much more easily, which could help reduce the foreign body response.

“The reactivity of titanium with high corrosion resistance, as revealed in this experiment by its electronic band structure, is one of the primary reasons for its excellent biocompatibility among metals,” says corresponding author Takao Hanawa. This research may lead to safer and less expensive implants for hip replacements or dental implants, because titanium is relatively rare and expensive.

The work is published in Science and Technology of Advanced Materials.


Simulations reveal role of calcium in titanium implant acceptance


More information:
Seong-Cheol Kim et al, Band structures of passive films on titanium in simulated bioliquids determined by photoelectrochemical response: principle governing the biocompatibility, Science and Technology of Advanced Materials (2022). DOI: 10.1080/14686996.2022.2066960

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Exploring what gives titanium implants their remarkable biocompatibility (2022, May 24)
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