Results 41 to 50 of about 3,881 (176)

In vitro assessment of expansion, mechanical stability, and cohesion across a panel of bone graft scaffolds

open access: yesMaterials Research Express
Background. Over 400 000 spinal fusions are performed annually in the United States, and nonunion has been reported in 5%–45% of cases, with graft selection contributing to this variability.
Douglas C Fredericks   +5 more
doaj   +1 more source

Evaluation of bioactive glass and demineralized freeze dried bone allograft in the treatment of periodontal intraosseous defects: A comparative clinico-radiographic study

open access: yesJournal of Indian Society of Periodontology, 2013
Aim: The purpose of this study was to evaluate the efficacy of demineralized freeze dried bone allograft (DFDBA) and bioactive glass by clinically and radiographically in periodontal intrabony defects for a period of 12 months. Materials and Methods: Ten
Kishore Kumar Katuri   +4 more
doaj   +1 more source

Hydrogels in Periodontal and Craniofacial Regeneration: Current Applications and Next‐Generation Biomaterials

open access: yesJournal of Periodontal Research, EarlyView.
Hydrogel‐based therapies have proven to be valuable tools to address the unique regeneration challenges of complex multi‐domain periodontal and craniofacial tissues. This review highlights and classifies clinically approved and emerging hydrogel therapies indicated for the regeneration of periodontal and craniofacial tissues.
Z. Gouveia   +5 more
wiley   +1 more source

Qualitative histologic evaluation of the tissue reaction to the polyurethane resin (ricinus communis - based biopolymer) implantation assessed by light and scanning electron microscopy

open access: yesPolímeros, 2013
The tissue reaction of bone tissue accessed by light microscopy and scanning electron microscopy (SEM) images after polyurethane resin implantation is presented in this study. Twenty four male rabbits were used, divided into two groups of 12 animals each
Gustavo Campos Belmonte   +5 more
doaj   +1 more source

Comparação das propriedades da osteocondução e osteointegração de uma hidroxiapatita reabsorvivel comercial sintetizada Comparación de las propiedades de osteoconducción y osteointegración de una hidroxiapatita reabsorbible comercial con una hidroxiapatita reabsorbible sintetizada</a> </p><span class="r_subtitle"><img src="/img/openaccess.ico" alt="open access: yes" title="open access: yes" width="16" height="16"><i>Revista Colombiana de Ciencias Pecuarias</i>, 2009 </span><br><span class="r_content">En el presente artículo se evalúan las propiedades de osteoconducción y osteointegración de una hidroxiapatita reabsorbible (OseoU), procesada a dos temperaturas diferentes de calcinación (Tipo A y Tipo B), con el propósito de compararlas con un ...</span><br><span class="r_sub"><i>Carlos D Jaramillo<span id="ma_5" style="display:none">, Jairo A Rivera, Alejandro Echavarría, Johan O'byrne, Diego Congote, Luis F Restrepo B</span>   <small><a href="#" style="color:#808080;" onClick="return toggle_div(this, 'ma_5')">+5 more</a></small></i></span><br><small><a href="https://doaj.org/article/803c2665c1c94e3b9b2f92e12ae5bb2f" target="_blank" rel="nofollow" title="doaj.org/article/803c2665c1c94e3b9b2f92e12ae5bb2f">doaj</a> </small>   <br></div><div class="r"><p class="r_title"><a href="https://doi.org/10.3390/biomedicines9020143" target="_blank" rel="nofollow">Collagen-Based Matrices for Osteoconduction: A Preclinical In Vivo Study</a> </p><span class="r_subtitle"><img src="/img/openaccess.ico" alt="open access: yes" title="open access: yes" width="16" height="16"><i>Biomedicines</i>, 2021 </span><br><span class="r_content">The aim of this study was to evaluate the influence of additional hydroxyapatite (HA) in collagen-based matrices (CM) and membrane placement on bone formation in calvarial defects.</span><br><span class="r_sub"><i>Hiroki Katagiri<span id="ma_6" style="display:none">, Yacine El Tawil, Niklaus P. Lang, Jean-Claude Imber, Anton Sculean, Masako Fujioka-Kobayashi, Nikola Saulacic</span>   <small><a href="#" style="color:#808080;" onClick="return toggle_div(this, 'ma_6')">+6 more</a></small></i></span><br><small><a href="https://doaj.org/article/46f498dec3ac471085e1cad4d47431de" target="_blank" rel="nofollow" title="doaj.org/article/46f498dec3ac471085e1cad4d47431de">doaj</a> </small>   <div id="more_6" style="display:none"><a href="/sci_redir.php?doi=10.3390%2Fbiomedicines9020143" target="_blank" rel="nofollow">openaccessbutton.org (pdf)</a><br><a href="javascript:navigator.clipboard.writeText('10.3390/biomedicines9020143'); alert('Copied the doi');">copy doi</a> <small>(10.3390/biomedicines9020143)</small><br></div><small><a href="#" onClick="return toggle_div(this, 'more_6')">+1 more source</a></small><br></div><div class="r"><p class="r_title"><a href="https://doi.org/10.1111/prd.70026" target="_blank" rel="nofollow">Long‐term stability of horizontal bone augmentation at implant sites</a> </p><span class="r_subtitle"><img src="/img/openaccess.ico" alt="open access: yes" title="open access: yes" width="16" height="16"><i>Periodontology 2000, EarlyView.</i></span><br><span class="r_content">Abstract Horizontal bone augmentation is a fundamental surgical procedure in regenerative implant dentistry. In recent decades, this procedure has evolved, enabling clinicians to achieve predictable and stable horizontal bone augmentation that supports dental implant restorations.</span><br><span class="r_sub"><i>Jia‐Hui Fu<span id="ma_7" style="display:none">, Hui Jia Sophia Choo, Ding‐Sen Ong, Henry Kwek</span>   <small><a href="#" style="color:#808080;" onClick="return toggle_div(this, 'ma_7')">+3 more</a></small></i></span><br><small><a href="https://onlinelibrary.wiley.com/doi/10.1111/prd.70026?mi=2or9o2m&af=R&AllField=osteoconduction&ConceptID=15941&content=articlesChapters&target=default" target="_blank" rel="nofollow" title="wiley.com/doi/10.1111/prd.70026?mi=2or9o2m&af=R&AllField=osteoconduction&ConceptID=15941&content=articlesChapters&target=default">wiley</a> </small>   <div id="more_7" style="display:none"><a href="/sci_redir.php?doi=10.1111%2Fprd.70026" target="_blank" rel="nofollow">openaccessbutton.org (pdf)</a><br><a href="javascript:navigator.clipboard.writeText('10.1111/prd.70026'); alert('Copied the doi');">copy doi</a> <small>(10.1111/prd.70026)</small><br></div><small><a href="#" onClick="return toggle_div(this, 'more_7')">+1 more source</a></small><br></div><div class="r"><p class="r_title"><a href="https://doi.org/10.1002/lsm.70126" target="_blank" rel="nofollow">Effects of Dual Wavelength Photobiomodulation on Osseointegration in Grafted Areas</a> </p><span class="r_subtitle"><img src="/img/openaccess.ico" alt="open access: yes" title="open access: yes" width="16" height="16"><i>Lasers in Surgery and Medicine, Volume 58, Issue 5, Page 429-436, July 2026.</i></span><br><span class="r_content">ABSTRACT Objective This study evaluated the effects of dual‐wavelength photobiomodulation (PBMT) (infrared and red laser) on osseointegration and bone structure in areas grafted with deproteinized bovine bone (DBB). Methods Sixty‐four rats were randomly distributed into four groups. The groups were divided according to the irradiation protocol applied: </span><br><span class="r_sub"><i>Lucas de Sousa Goulart Pereira<span id="ma_8" style="display:none">, Julia Raulino Lima, Elcio Marcantonio Jr., Priscilla Barbosa Ferreira Soares, Suzane Cristina Pigossi, Guilherme José Pimentel Lopes de Oliveira</span>   <small><a href="#" style="color:#808080;" onClick="return toggle_div(this, 'ma_8')">+5 more</a></small></i></span><br><small><a href="https://onlinelibrary.wiley.com/doi/10.1002/lsm.70126?mi=2or9o2m&af=R&AllField=osteoconduction&ConceptID=15941&content=articlesChapters&target=default" target="_blank" rel="nofollow" title="wiley.com/doi/10.1002/lsm.70126?mi=2or9o2m&af=R&AllField=osteoconduction&ConceptID=15941&content=articlesChapters&target=default">wiley</a> </small>   <div id="more_8" style="display:none"><a href="/sci_redir.php?doi=10.1002%2Flsm.70126" target="_blank" rel="nofollow">openaccessbutton.org (pdf)</a><br><a href="javascript:navigator.clipboard.writeText('10.1002/lsm.70126'); alert('Copied the doi');">copy doi</a> <small>(10.1002/lsm.70126)</small><br></div><small><a href="#" onClick="return toggle_div(this, 'more_8')">+1 more source</a></small><br></div><div class="r"><p class="r_title"><a href="https://doi.org/10.1007/s13191-012-0145-6" target="_blank" rel="nofollow">Titanium Dioxide as an Osteoconductive Material: An Animal Study</a> </p><span class="r_subtitle"><img src="/img/openaccess.ico" alt="open access: yes" title="open access: yes" width="16" height="16"><i>The Journal of Indian Prosthodontic Society</i>, 2012 </span><br><span class="r_content">The purpose of the present study was to evaluate the biocompatibility and osteoconductive potential of pure and pigment forms of titanium dioxide. Pure and pigment forms of titanium dioxide were incorporated into prepared bur holes in the femur bone of rabbits. Implantation was done on six Albino rabbits which were sacrificed at the end of 3rd, 4th and </span><br><span class="r_sub"><i>Karunakaran, Harshakumar<span id="ma_9" style="display:none">, K Chandrasekharan, Nair, N George, Paulose, Vivek V, Nair, V, Prasanth, Aswathi, Krishnan</span>   <small><a href="#" style="color:#808080;" onClick="return toggle_div(this, 'ma_9')">+5 more</a></small></i></span><br><small><a href="https://explore.openaire.eu/search/publication?pid=10.1007%2Fs13191-012-0145-6" target="_blank" rel="nofollow" title="openaire.eu/search/publication?pid=10.1007%2Fs13191-012-0145-6">openaire</a> </small>   <div id="more_9" style="display:none"><a href="/sci_redir.php?doi=10.1007%2Fs13191-012-0145-6" target="_blank" rel="nofollow">openaccessbutton.org (pdf)</a><br><a href="https://pubmed.ncbi.nlm.nih.gov/24431717" target="_blank" rel="nofollow" title="pubmed.ncbi.nlm.nih.gov/24431717">pubmed.ncbi.nlm.nih.gov</a><br> <a href="javascript:navigator.clipboard.writeText('10.1007/s13191-012-0145-6'); alert('Copied the doi');">copy doi</a> <small>(10.1007/s13191-012-0145-6)</small><br></div><small><a href="#" onClick="return toggle_div(this, 'more_9')">+2 more sources</a></small><br></div><div class="r"><p class="r_title"><a href="https://doi.org/10.1002/med.70039" target="_blank" rel="nofollow">Biodegradable Natural Polymer‐Based Drug Delivery Systems for Bone Tissue Engineering</a> </p><span class="r_subtitle"><img src="/img/openaccess.ico" alt="open access: yes" title="open access: yes" width="16" height="16"><i>Medicinal Research Reviews, Volume 46, Issue 4, Page 966-988, July 2026.</i></span><br><span class="r_content">ABSTRACT The increasing incidence of bone diseases and injuries, especially among aging populations, has underscored the shortcomings of traditional treatments such as bone grafts and metal implants, which often face complications including immune rejection, mechanical failure, and delayed healing.</span><br><span class="r_sub"><i>Hyejin Jo<span id="ma_10" style="display:none">, Shinwon Kang, Jae Eun Yang, Inseon Kim, Seunghun S. Lee</span>   <small><a href="#" style="color:#808080;" onClick="return toggle_div(this, 'ma_10')">+4 more</a></small></i></span><br><small><a href="https://onlinelibrary.wiley.com/doi/10.1002/med.70039?mi=2or9o2m&af=R&AllField=osteoconduction&ConceptID=15941&content=articlesChapters&target=default" target="_blank" rel="nofollow" title="wiley.com/doi/10.1002/med.70039?mi=2or9o2m&af=R&AllField=osteoconduction&ConceptID=15941&content=articlesChapters&target=default">wiley</a> </small>   <div id="more_10" style="display:none"><a href="/sci_redir.php?doi=10.1002%2Fmed.70039" target="_blank" rel="nofollow">openaccessbutton.org (pdf)</a><br><a href="javascript:navigator.clipboard.writeText('10.1002/med.70039'); alert('Copied the doi');">copy doi</a> <small>(10.1002/med.70039)</small><br></div><small><a href="#" onClick="return toggle_div(this, 'more_10')">+1 more source</a></small><br></div><div class="r"><div style="margin-bottom:2px;overflow:hidden"><div style="display: inline-block; float: left; font-size: small; padding-right: 16px; margin-top: -1px; padding-bottom: 1px;"><a href="/q-osteoinduction/" class="suggestion"onclick="show_loader();"><b>osteoinduction</b></a><br/><a href="/q-bone_regeneration/" class="suggestion"onclick="show_loader();"><b>bone regeneration</b></a><br/><a href="/q-hydroxyapatite/" class="suggestion"onclick="show_loader();"><b>hydroxyapatite</b></a><br/></div><div style="display: inline-block; float: left; font-size: small; padding-right: 16px; margin-top: -1px; padding-bottom: 1px;"><a href="/q-biocompatibility/" class="suggestion"onclick="show_loader();"><b>biocompatibility</b></a><br/><a href="/q-biomaterials/" class="suggestion"onclick="show_loader();"><b>biomaterials</b></a><br/><a href="/q-hidroxiapatita/" class="suggestion"onclick="show_loader();"><b>hidroxiapatita</b></a><br/></div><div style="display: inline-block; float: left; font-size: small; padding-right: 16px; margin-top: -1px; padding-bottom: 1px;"><a href="/q-osseointegration/" class="suggestion"onclick="show_loader();"><b>osseointegration</b></a><br/><a href="/q-osteogenesis/" class="suggestion"onclick="show_loader();"><b>osteogenesis</b></a><br/><a href="/q-regenera%C3%A7%C3%A3o_%C3%B3ssea/" class="suggestion"onclick="show_loader();"><b>regeneração óssea</b></a><br/></div></div></div><div class="pagenav"><a href="/q-osteoconduction/p-4/" rel="nofollow"><b>previous</b></a>   <a href="/q-osteoconduction/p-3/" rel="nofollow">3</a>  <a href="/q-osteoconduction/p-4/" rel="nofollow">4</a>  <b>5</b>  <a href="/q-osteoconduction/p-6/" rel="nofollow">6</a>  <a href="/q-osteoconduction/p-7/" rel="nofollow">7</a>   <a href="/q-osteoconduction/p-6/" id="next" rel="nofollow"><b>next</b></a> </div><br></div> </div> <script>document.getElementById('loadingGif').style.display='none';</script><div style="width: 100%; height: 40px; bottom: 0px; background-color: #f5f5f5;"><div style="padding-left: 15px; padding-top: 10px"> <a href="/" rel="nofollow">Home</a> - <a href="/page-about/" rel="nofollow">About</a> - <a href="/page-disclaimer/" rel="nofollow">Disclaimer</a> - <a href="/page-privacy/" rel="nofollow">Privacy</a> </div></div> <link rel="stylesheet" href="//ajax.googleapis.com/ajax/libs/jqueryui/1.11.4/themes/smoothness/jquery-ui.min.css"/> <script> (function(ss,ex){ window.ldfdr=window.ldfdr||function(){(ldfdr._q=ldfdr._q||[]).push([].slice.call(arguments));}; (function(d,s){ fs=d.getElementsByTagName(s)[0]; function ce(src){ var cs=d.createElement(s); cs.src=src; cs.async=1; fs.parentNode.insertBefore(cs,fs); }; ce('https://sc.lfeeder.com/lftracker_v1_'+ss+(ex?'_'+ex:'')+'.js'); })(document,'script'); })('JMvZ8gvrWA9a2pOd'); </script> </body> </html>