Tag Archives: Sherif Elsharkawy

Protect and repair damaged teeth with toothpaste made from your own hair?

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Intriguing, non? An August 13 , 2025 King’s College London press release (also on EurekAlert) describes work that could save your teeth in years to come, Note: A video of the researcher, Dr Sherif Elsharkawy, describing his work is embedded in the King’s College London press release,

Toothpaste made from your own hair may offer a sustainable and clinically effective way to protect and repair damaged teeth.

In a new study published today, scientists discovered that keratin, a protein found in hair, skin and wool, can repair tooth enamel and stop early stages of decay.

The King’s College London team of scientists discovered that keratin produces a protective coating that mimics the structure and function of natural enamel when it comes into contact with minerals in saliva.

Dr Sherif Elsharkawy, senior author and consultant in prosthodontics at King’s College London, said: “Unlike bones and hair, enamel does not regenerate, once it is lost, it’s gone forever.”

Acidic foods and drinks, poor oral hygiene, and ageing all contribute to enamel erosion and decay, leading to tooth sensitivity, pain and eventually tooth loss.

While fluoride toothpastes are currently used to slow this process, keratin-based treatments were found to stop it completely. Keratin forms a dense mineral layer that protects the tooth and seals off exposed nerve channels that cause sensitivity, offering both structural and symptomatic relief.

The treatment could be delivered through a toothpaste for daily use or as a professionally applied gel, similar to nail varnish, for more targeted repair. The team is already exploring pathways for clinical application and believes that keratin-based enamel regeneration could be made available to the public within the next two to three years.

In their study, published in Advanced Healthcare Materials, the scientists extracted keratin from wool. They discovered that when keratin is applied to the tooth surface and comes into contact with the minerals naturally present in saliva, it forms a highly organised, crystal-like scaffold that mimics the structure and function of natural enamel.

Over time, this scaffold continues to attract calcium and phosphate ions, leading to the growth of a protective enamel-like coating around the tooth. This marks a significant step forward in regenerative dentistry.

Sara Gamea, PhD researcher at King’s College London and first author of the study, added: “Keratin offers a transformative alternative to current dental treatments. Not only is it sustainably sourced from biological waste materials like hair and skin, it also eliminates the need for traditional plastic resins, commonly used in restorative dentistry, which are toxic and less durable. Keratin also looks much more natural than these treatments, as it can more closely match the colour of the original tooth.”

As concerns grow over the sustainability of healthcare materials and long-term fluoride use, this discovery positions keratin as a leading candidate for future dental care. The research also aligns with broader efforts to embrace circular, waste-to-health innovations, transforming what would otherwise be discarded into a valuable clinical resource.

Sara Gamea said: “This technology bridges the gap between biology and dentistry, providing an eco-friendly biomaterial that mirrors natural processes.”

Dr Elsharkawy concluded: “We are entering an exciting era where biotechnology allows us to not just treat symptoms but restore biological function using the body’s own materials. With further development and the right industry partnerships, we may soon be growing stronger, healthier smiles from something as simple as a haircut.”

[diagram downloaded from https://www.kcl.ac.uk/news/toothpaste-made-from-hair-provides-natural-root-to-repair-teeth]

Here’s a link to and a citation for the paper,

Biomimetic Mineralization of Keratin Scaffolds for Enamel Regeneration by Sara Gamea, Elham Radvar, Dimitra Athanasiadou, Ryan Lee Chan, Giacomo De Sero, Ecaterina Ware, Sunie Kundi, Avir Patel, Shwan Horamee, Shuaib Hadadi, Mads Carlsen, Leanne Allison, Roland Fleck, Ka Lung Andrew Chan, Avijit Banerjee, Nicola Pugno, Marianne Liebi, Paul T Sharpe, Karina Carneiro, Sherif Elsharkawy. Advanced Healthcare Materials DOI: https://doi.org/10.1002/adhm.202502465 First published online: 12 August 2025

This paper is open access.

Regenerating dental enamel

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For anyone who’s concerned about their dental enamel, this research might prove encouraging. From a June 1, 2018 news item on Nanowerk,

Researchers at Queen Mary University of London [UK][ have developed a new way to grow mineralised materials which could regenerate hard tissues such as dental enamel and bone.

Enamel, located on the outer part of our teeth, is the hardest tissue in the body and enables our teeth to function for a large part of our lifetime despite biting forces, exposure to acidic foods and drinks and extreme temperatures. This remarkable performance results from its highly organised structure.

However, unlike other tissues of the body, enamel cannot regenerate once it is lost, which can lead to pain and tooth loss. These problems affect more than 50 per cent of the world’s population and so finding ways to recreate enamel has long been a major need in dentistry.

A June 1, 2018 Queen Mary University of London press release, which originated the news item, provides more detail,

The study, published in Nature Communications, shows that this new approach can create materials with remarkable precision and order that look and behave like dental enamel.

The materials could be used for a wide variety of dental complications such as the prevention and treatment of tooth decay or tooth sensitivity – also known as dentin hypersensitivity.

Simple and versatile

Dr Sherif Elsharkawy, a dentist and first author of the study from Queen Mary’s School of Engineering and Materials Science, said: “This is exciting because the simplicity and versatility of the mineralisation platform opens up opportunities to treat and regenerate dental tissues. For example, we could develop acid resistant bandages that can infiltrate, mineralise, and shield exposed dentinal tubules of human teeth for the treatment of dentin hypersensitivity.”

The mechanism that has been developed is based on a specific protein material that is able to trigger and guide the growth of apatite nanocrystals at multiple scales – similarly to how these crystals grow when dental enamel develops in our body. This structural organisation is critical for the outstanding physical properties exhibited by natural dental enamel.

Lead author Professor Alvaro Mata, also from Queen Mary’s School of Engineering and Materials Science, said: “A major goal in materials science is to learn from nature to develop useful materials based on the precise control of molecular building-blocks. The key discovery has been the possibility to exploit disordered proteins to control and guide the process of mineralisation at multiple scales. Through this, we have developed a technique to easily grow synthetic materials that emulate such hierarchically organised architecture over large areas and with the capacity to tune their properties.”

Mimic other hard tissues

Enabling control of the mineralisation process opens the possibility to create materials with properties that mimic different hard tissues beyond enamel such as bone and dentin. As such, the work has the potential to be used in a variety of applications in regenerative medicine. In addition, the study also provides insights into the role of protein disorder in human physiology and pathology.

Here’s a link to and a citation for the paper,

Protein disorder–order interplay to guide the growth of hierarchical mineralized structures by Sherif Elsharkawy, Maisoon Al-Jawad, Maria F. Pantano, Esther Tejeda-Montes, Khushbu Mehta, Hasan Jamal, Shweta Agarwal, Kseniya Shuturminska, Alistair Rice, Nadezda V. Tarakina, Rory M. Wilson, Andy J. Bushby, Matilde Alonso, Jose C. Rodriguez-Cabello, Ettore Barbieri, Armando del Río Hernández, Molly M. Stevens, Nicola M. Pugno, Paul Anderson, & Alvaro Mata. Nature Communicationsvolume 9, Article number: 2145 (2018) Published 01 June 2018 DOI: https://doi.org/10.1038/s41467-018-04319-0

This paper is open access.

One final comment, this work is at the ‘in vitro’ stage. More colloquially, this is being done in a petri dish or glass vial or some other container and it’s going to be a long time before there are going to be any human clinical trials, assuming the work gets that far.