2018
DOI: 10.1002/adhm.201800467
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Bioinspired Mineral–Organic Bioresorbable Bone Adhesive

Abstract: Bioresorbable bone adhesives have potential to revolutionize the clinical treatment of the human skeletal system, ranging from the fixation and osteointegration of permanent implants to the direct healing and fusion of bones without permanent fixation hardware. Despite an unmet need, there are currently no bone adhesives in clinical use that provide a strong enough bond to wet bone while possessing good osteointegration and bioresorbability. Inspired by the sandcastle worm that creates a protective tubular she… Show more

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Cited by 62 publications
(153 citation statements)
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References 80 publications
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“…Conventional technologies, including the use of metallic plates and screws, are safe and serviceable but often suffer from foreign‐body reactions, aseptic loosening, and the need to be surgically replaced or removed . Bone adhesives, such as poly(methyl methacrylate) (PMMA) and calcium phosphate (CPC) bone cements, are gaining special attention as alternative treatments that have the potential to revolutionize procedures towards more personalized bone repair . Despite their routine use, severe deficiencies remain in current products, including cytotoxicity concerns, inappropriate mechanical strength, poor fixation performance in biological environments, and consequently notoriously high failure rates for bone healing .…”
Section: Introductionmentioning
confidence: 99%
“…Conventional technologies, including the use of metallic plates and screws, are safe and serviceable but often suffer from foreign‐body reactions, aseptic loosening, and the need to be surgically replaced or removed . Bone adhesives, such as poly(methyl methacrylate) (PMMA) and calcium phosphate (CPC) bone cements, are gaining special attention as alternative treatments that have the potential to revolutionize procedures towards more personalized bone repair . Despite their routine use, severe deficiencies remain in current products, including cytotoxicity concerns, inappropriate mechanical strength, poor fixation performance in biological environments, and consequently notoriously high failure rates for bone healing .…”
Section: Introductionmentioning
confidence: 99%
“…A number of adhesives have been proposed for fracture repair, including acrylate-based glue [12], collagen or fibrin glues [13], click chemistry-based glues [14], and, more recently, adhesive ceramics [15][16][17]. While naturally derived adhesives, such as fibrin glue (Tisseel), are cyto-and biocompatible and may retain biologic elements that enhance healing, their bond strengths KiloPascal (KPa) are relatively poor compared to the properties of cancellous and cortical bone [11,18].…”
Section: Introductionmentioning
confidence: 99%
“…(A) Different curing environments (phosphate-buffered saline (PBS), water, or 100% humidity) and grip duration (24 h, blue box; or 5 min, red box) before curing did not affect the adhesive strength of 27% PMC (from left to right: groups #1, 4, 2, 5, 3, 6). (B) When the grip duration was shortened and the grip force reduced to mimic clinical conditions, comparable adhesive strength was observed in all samples except the automated mixing sample (red border) and low grip force (3 N) samples gripped for 5 min (from left to right: groups #3, 9,6,10,7,11,8,12,33,34; the red border indicates high speed mixing; green border indicates bone samples). (C) Different mole ratios of phosphoserine to αTCP, and cure conditions, affected adhesive strengths (from left to right: groups #3, 14, 15; 19-21; 13, 16-18) (100% humidity samples were gripped for 1 min).…”
Section: Surface Roughness Of Test Cubesmentioning
confidence: 96%
“…Coacervation and nanoscale electrostatic interactions are also sufficient to create relatively strong tissue adhesion [4][5][6][7]. Recently, strong adhesion has been created in biomaterials that are not adhesive (bioceramics) by incorporating a modified amino acid (phosphoserine) [8][9][10]. Phosphoserine-modified cements (PMCs) display a unique microstructure, appearing amorphous rather than crystalline [10], can stabilize bioactive phases and remodel into precursors of hydroxyapatite [11], and display significantly improved healing, compared to unmodified cements [12][13][14][15].…”
Section: Introductionmentioning
confidence: 99%
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