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<article xlink="http://www.w3.org/1999/xlink" dtd-version="1.0" article-type="dentistry" lang="en">
  <front>
    <journal-meta>
      <journal-id journal-id-type="publisher">JOHS</journal-id>
      <journal-id journal-id-type="nlm-ta">Journ of Health Scien</journal-id>
      <journal-title-group>
        <journal-title>Journal of HealthCare Sciences</journal-title>
        <abbrev-journal-title abbrev-type="pubmed">Journ of Health Scien</abbrev-journal-title>
      </journal-title-group>
      <issn pub-type="ppub">2231-2196</issn>
      <issn pub-type="opub">0975-5241</issn>
      <publisher>
        <publisher-name>Radiance Research Academy</publisher-name>
      </publisher>
    </journal-meta>
    <article-meta>
      <article-id pub-id-type="publisher-id">409</article-id>
      <article-id pub-id-type="doi">http://dx.doi.org/10.52533/JOHS.2025.50703</article-id>
      <article-id pub-id-type="doi-url"/>
      <article-categories>
        <subj-group subj-group-type="heading">
          <subject>Dentistry</subject>
        </subj-group>
      </article-categories>
      <title-group>
        <article-title>Bioactive Restorative Materials: The Intersection of Restoration and Regeneration&#13;
</article-title>
      </title-group>
      <contrib-group>
        <contrib contrib-type="author">
          <name>
            <surname>Alshahrani</surname>
            <given-names>Mohammed Thamer</given-names>
          </name>
        </contrib>
        <contrib contrib-type="author">
          <name>
            <surname>Rubehan</surname>
            <given-names>Reem Abdulkareem</given-names>
          </name>
        </contrib>
        <contrib contrib-type="author">
          <name>
            <surname>AlJohani</surname>
            <given-names>Samer Masad</given-names>
          </name>
        </contrib>
      </contrib-group>
      <pub-date pub-type="ppub">
        <day>21</day>
        <month>07</month>
        <year>2025</year>
      </pub-date>
      <volume>5</volume>
      <issue>7</issue>
      <fpage>256</fpage>
      <lpage>262</lpage>
      <permissions>
        <copyright-statement>This article is copyright of Popeye Publishing, 2009</copyright-statement>
        <copyright-year>2009</copyright-year>
        <license license-type="open-access" href="http://creativecommons.org/licenses/by/4.0/">
          <license-p>This is an open-access article distributed under the terms of the Creative Commons Attribution (CC BY 4.0) Licence. You may share and adapt the material, but must give appropriate credit to the source, provide a link to the licence, and indicate if changes were made.</license-p>
        </license>
      </permissions>
      <abstract>
        <p>Bioactive restorative materials (BRM) have led to a paradigm shift in the field of restorative dentistry. These hybrid materials function like traditional dental-restorative materials–metals and ceramics–while also acting as physiologically active substitutes. Their interaction with the oral environment facilitates remineralization, enhances bonding, and supports tissue regeneration. These release calcium, phosphate, or fluoride ions, which are crucial for remineralizing demineralized enamel and dentin, thereby prolonging the lifespan of restorations. BRM combines restoration and regeneration, providing mechanical support similar to conventional materials while also stimulating the healing of the tooth structures. These materials are valuable for direct and indirect restorations, root canal treatments, and pulp capping procedures due to their ability to encourage odontoblast activity and stimulate hydroxyapatite formation. Their benefits include improved biocompatibility, significant reduction in secondary caries, and better patient outcomes. However, limitations such as material degradation, low mechanical strength, and high costs, hinder widespread application. Ongoing efforts to improve the material composition and develop new formulations aim to overcome these barriers. Future advancements will focus on improving mechanical properties, bioactivity, and nanotechnology integration to achieve optimal clinical performance. Researchers are working to develop multifunctional restorative materials with antibacterial properties and controlled ion release, contributing to sustainable improvements in oral health. The next generation of BRM will be driven by innovations in biomaterials science, providing more effective and long-lasting solutions for restorative dentistry.&#13;
</p>
      </abstract>
      <kwd-group>
        <kwd>bioactive</kwd>
        <kwd> restorative materials</kwd>
        <kwd> restoration</kwd>
        <kwd> regeneration</kwd>
        <kwd> pulp</kwd>
        <kwd> dental</kwd>
        <kwd> oral</kwd>
        <kwd> dentistry</kwd>
        <kwd> dentin</kwd>
        <kwd> tooth</kwd>
        <kwd> tooth structure</kwd>
      </kwd-group>
    </article-meta>
  </front>
</article>