A prospective, randomised, controlled trial using a Mg-hydroxyapatite - demineralized bone matrix nanocomposite in tibial osteotomy

We in vivo investigated the bone healing ability of a nanocomposite (DBSint®), constituted by biomimetic nano-structured Mg-hydroxyapatite (SINTlife®) and human demineralized bone matrix. Thirty-one subjects undergoing high tibial osteotomy for genu varus were randomly assigned to three groups: duri...

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Published inBiomaterials Vol. 33; no. 1; pp. 72 - 79
Main Authors Dallari, Dante, Savarino, Lucia, Albisinni, Ugo, Fornasari, Piermaria, Ferruzzi, Alberto, Baldini, Nicola, Giannini, Sandro
Format Journal Article
LanguageEnglish
Published Netherlands Elsevier Ltd 01.01.2012
Subjects
Adult
Advanced Basic Science
biomimetics
biopsy
Bone healing
Bone Matrix - chemistry
clinical trials
Demineralized bone matrix
Dentistry
Durapatite - chemistry
Female
freeze drying
Humans
image analysis
Male
Middle Aged
Nano-structured Mg-hydroxyapatite
nanocomposites
Nanocomposites - chemistry
Nanocomposites - therapeutic use
Osteotomy
Osteotomy - methods
patients
Radiography
tibia
Tibia - diagnostic imaging
Tibia - surgery
Young Adult
Demineralized bone matrix
Bone healing
Osteotomy
Nano-structured Mg-hydroxyapatite
Online AccessGet full text
ISSN0142-9612
1878-5905
1878-5905
DOI10.1016/j.biomaterials.2011.09.029

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Abstract We in vivo investigated the bone healing ability of a nanocomposite (DBSint®), constituted by biomimetic nano-structured Mg-hydroxyapatite (SINTlife®) and human demineralized bone matrix. Thirty-one subjects undergoing high tibial osteotomy for genu varus were randomly assigned to three groups: during surgery, DBSint® was inserted into nine patients, SINTlife® in thirteen patients and lyophilised bone chips, that is the routine surgery, in nine subjects. As outcome measures, clinical, radiographic and histomorphometry scores were calculated. The osseointegration was evaluated by imaging six weeks, three, six and twelve months after surgery. At six-week follow-up, DBSint® showed a significantly higher osseointegration rate in comparison with lyophilised bone chips ( p = 0.008). At the same follow-up, CT-guided bone biopsies were obtained and analysed by histomorphometry: a good osteogenetic potential was demonstrated with DBSint®, as well as with SINTlife® and controls. Unresorbed material was evident with DBSint® and SINTlife®, with a significantly higher percentage in SINTlife® group. At 1-year follow-up, DBSint® was demonstrated as effective and safe as SINTlife® and lyophilized bone chips. More significant results could be obtained by continuing the clinical trial, by increasing the patient number and the study power. Eventually, the role of non-resorbed graft remnants is still unclear and requires further investigation.
AbstractList We in vivo investigated the bone healing ability of a nanocomposite (DBSint®), constituted by biomimetic nano-structured Mg-hydroxyapatite (SINTlife®) and human demineralized bone matrix. Thirty-one subjects undergoing high tibial osteotomy for genu varus were randomly assigned to three groups: during surgery, DBSint® was inserted into nine patients, SINTlife® in thirteen patients and lyophilised bone chips, that is the routine surgery, in nine subjects. As outcome measures, clinical, radiographic and histomorphometry scores were calculated. The osseointegration was evaluated by imaging six weeks, three, six and twelve months after surgery. At six-week follow-up, DBSint® showed a significantly higher osseointegration rate in comparison with lyophilised bone chips ( p = 0.008). At the same follow-up, CT-guided bone biopsies were obtained and analysed by histomorphometry: a good osteogenetic potential was demonstrated with DBSint®, as well as with SINTlife® and controls. Unresorbed material was evident with DBSint® and SINTlife®, with a significantly higher percentage in SINTlife® group. At 1-year follow-up, DBSint® was demonstrated as effective and safe as SINTlife® and lyophilized bone chips. More significant results could be obtained by continuing the clinical trial, by increasing the patient number and the study power. Eventually, the role of non-resorbed graft remnants is still unclear and requires further investigation.
We in vivo investigated the bone healing ability of a nanocomposite (DBSint®), constituted by biomimetic nano-structured Mg-hydroxyapatite (SINTlife®) and human demineralized bone matrix. Thirty-one subjects undergoing high tibial osteotomy for genu varus were randomly assigned to three groups: during surgery, DBSint® was inserted into nine patients, SINTlife® in thirteen patients and lyophilised bone chips, that is the routine surgery, in nine subjects. As outcome measures, clinical, radiographic and histomorphometry scores were calculated. The osseointegration was evaluated by imaging six weeks, three, six and twelve months after surgery. At six-week follow-up, DBSint® showed a significantly higher osseointegration rate in comparison with lyophilised bone chips (p = 0.008). At the same follow-up, CT-guided bone biopsies were obtained and analysed by histomorphometry: a good osteogenetic potential was demonstrated with DBSint®, as well as with SINTlife® and controls. Unresorbed material was evident with DBSint® and SINTlife®, with a significantly higher percentage in SINTlife® group. At 1-year follow-up, DBSint® was demonstrated as effective and safe as SINTlife® and lyophilized bone chips. More significant results could be obtained by continuing the clinical trial, by increasing the patient number and the study power. Eventually, the role of non-resorbed graft remnants is still unclear and requires further investigation.
Abstract We in vivo investigated the bone healing ability of a nanocomposite (DBSint®), constituted by biomimetic nano-structured Mg-hydroxyapatite (SINTlife®) and human demineralized bone matrix. Thirty-one subjects undergoing high tibial osteotomy for genu varus were randomly assigned to three groups: during surgery, DBSint® was inserted into nine patients, SINTlife® in thirteen patients and lyophilised bone chips, that is the routine surgery, in nine subjects. As outcome measures, clinical, radiographic and histomorphometry scores were calculated. The osseointegration was evaluated by imaging six weeks, three, six and twelve months after surgery. At six-week follow-up, DBSint® showed a significantly higher osseointegration rate in comparison with lyophilised bone chips ( p = 0.008). At the same follow-up, CT-guided bone biopsies were obtained and analysed by histomorphometry: a good osteogenetic potential was demonstrated with DBSint®, as well as with SINTlife® and controls. Unresorbed material was evident with DBSint® and SINTlife®, with a significantly higher percentage in SINTlife® group. At 1-year follow-up, DBSint® was demonstrated as effective and safe as SINTlife® and lyophilized bone chips. More significant results could be obtained by continuing the clinical trial, by increasing the patient number and the study power. Eventually, the role of non-resorbed graft remnants is still unclear and requires further investigation.
We in vivo investigated the bone healing ability of a nanocomposite (DBSint registered ), constituted by biomimetic nano-structured Mg-hydroxyapatite (SINTlife registered ) and human demineralized bone matrix. Thirty-one subjects undergoing high tibial osteotomy for genu varus were randomly assigned to three groups: during surgery, DBSint registered was inserted into nine patients, SINTlife registered in thirteen patients and lyophilised bone chips, that is the routine surgery, in nine subjects. As outcome measures, clinical, radiographic and histomorphometry scores were calculated. The osseointegration was evaluated by imaging six weeks, three, six and twelve months after surgery. At six-week follow-up, DBSint registered showed a significantly higher osseointegration rate in comparison with lyophilised bone chips (p = 0.008). At the same follow-up, CT-guided bone biopsies were obtained and analysed by histomorphometry: a good osteogenetic potential was demonstrated with DBSint registered , as well as with SINTlife registered and controls. Unresorbed material was evident with DBSint registered and SINTlife registered , with a significantly higher percentage in SINTlife registered group. At 1-year follow-up, DBSint registered was demonstrated as effective and safe as SINTlife registered and lyophilized bone chips. More significant results could be obtained by continuing the clinical trial, by increasing the patient number and the study power. Eventually, the role of non-resorbed graft remnants is still unclear and requires further investigation.
We in vivo investigated the bone healing ability of a nanocomposite (DBSint®), constituted by biomimetic nano-structured Mg-hydroxyapatite (SINTlife®) and human demineralized bone matrix. Thirty-one subjects undergoing high tibial osteotomy for genu varus were randomly assigned to three groups: during surgery, DBSint® was inserted into nine patients, SINTlife® in thirteen patients and lyophilised bone chips, that is the routine surgery, in nine subjects. As outcome measures, clinical, radiographic and histomorphometry scores were calculated. The osseointegration was evaluated by imaging six weeks, three, six and twelve months after surgery. At six-week follow-up, DBSint® showed a significantly higher osseointegration rate in comparison with lyophilised bone chips (p = 0.008). At the same follow-up, CT-guided bone biopsies were obtained and analysed by histomorphometry: a good osteogenetic potential was demonstrated with DBSint®, as well as with SINTlife® and controls. Unresorbed material was evident with DBSint® and SINTlife®, with a significantly higher percentage in SINTlife® group. At 1-year follow-up, DBSint® was demonstrated as effective and safe as SINTlife® and lyophilized bone chips. More significant results could be obtained by continuing the clinical trial, by increasing the patient number and the study power. Eventually, the role of non-resorbed graft remnants is still unclear and requires further investigation.We in vivo investigated the bone healing ability of a nanocomposite (DBSint®), constituted by biomimetic nano-structured Mg-hydroxyapatite (SINTlife®) and human demineralized bone matrix. Thirty-one subjects undergoing high tibial osteotomy for genu varus were randomly assigned to three groups: during surgery, DBSint® was inserted into nine patients, SINTlife® in thirteen patients and lyophilised bone chips, that is the routine surgery, in nine subjects. As outcome measures, clinical, radiographic and histomorphometry scores were calculated. The osseointegration was evaluated by imaging six weeks, three, six and twelve months after surgery. At six-week follow-up, DBSint® showed a significantly higher osseointegration rate in comparison with lyophilised bone chips (p = 0.008). At the same follow-up, CT-guided bone biopsies were obtained and analysed by histomorphometry: a good osteogenetic potential was demonstrated with DBSint®, as well as with SINTlife® and controls. Unresorbed material was evident with DBSint® and SINTlife®, with a significantly higher percentage in SINTlife® group. At 1-year follow-up, DBSint® was demonstrated as effective and safe as SINTlife® and lyophilized bone chips. More significant results could be obtained by continuing the clinical trial, by increasing the patient number and the study power. Eventually, the role of non-resorbed graft remnants is still unclear and requires further investigation.
Author Baldini, Nicola
Albisinni, Ugo
Ferruzzi, Alberto
Savarino, Lucia
Giannini, Sandro
Fornasari, Piermaria
Dallari, Dante
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Issue 1
Keywords Demineralized bone matrix
Bone healing
Osteotomy
Nano-structured Mg-hydroxyapatite
Language English
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Snippet We in vivo investigated the bone healing ability of a nanocomposite (DBSint®), constituted by biomimetic nano-structured Mg-hydroxyapatite (SINTlife®) and...
Abstract We in vivo investigated the bone healing ability of a nanocomposite (DBSint®), constituted by biomimetic nano-structured Mg-hydroxyapatite (SINTlife®)...
We in vivo investigated the bone healing ability of a nanocomposite (DBSint®), constituted by biomimetic nano-structured Mg-hydroxyapatite (SINTlife®) and...
We in vivo investigated the bone healing ability of a nanocomposite (DBSint registered ), constituted by biomimetic nano-structured Mg-hydroxyapatite (SINTlife...
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StartPage 72
SubjectTerms Adult
Advanced Basic Science
biomimetics
biopsy
Bone healing
Bone Matrix - chemistry
clinical trials
Demineralized bone matrix
Dentistry
Durapatite - chemistry
Female
freeze drying
Humans
image analysis
Male
Middle Aged
Nano-structured Mg-hydroxyapatite
nanocomposites
Nanocomposites - chemistry
Nanocomposites - therapeutic use
Osteotomy
Osteotomy - methods
patients
Radiography
tibia
Tibia - diagnostic imaging
Tibia - surgery
Young Adult
Title A prospective, randomised, controlled trial using a Mg-hydroxyapatite - demineralized bone matrix nanocomposite in tibial osteotomy
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https://www.ncbi.nlm.nih.gov/pubmed/21955688
https://www.proquest.com/docview/1710228402
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https://www.proquest.com/docview/911154995
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