生物可吸收的骨替代材料3D支架,iNNOTERE 3D Scaffold
型号:内详
联系人:李先生
联系电话:18618101725
品牌:德国innotere
生物可吸收的骨替代材料3D支架,iNNOTERE 3D Scaffold
NNOTERE 3D支架是一种合成的,多孔的,生物相容的且具有生物可吸收性的骨替代材料,用于填充或重建不承重的骨缺损或用于填充骨缺损,这些骨缺损已通过适当的方式进行了充分稳定。与传统的预制骨替代品相比,INNOTERE 3D支架的特点是:
●互连孔隙
●使用合成原材料的骨状矿物相
●可通过骨骼重塑过程吸收
INNOTERE 3D支架的创新功能来自使用INNOTERE的创新磷酸钙骨水泥浆的新3D打印技术。该方法允许j确地调节所得支架的互连孔系统的孔隙率。用过的磷酸钙糊剂在印刷过程之后通过te定的固化程序进行固化,而wu需任何烧结步骤。这避免了晶体的生长,并导致支架主要由天然骨骼的矿相微晶羟基磷灰石组成。
INNOTERE 3D支架的te定应用领域是:
●干defect端骨折,例如胫骨,radius骨和肱骨骨折
●良性肿瘤和囊肿切除后的骨缺损
●口腔颌面外科手术中的骨缺损
●填充脊髓笼
订单详细信息
商品编号:121TS1 —骨替代物块10x10x5mm商品编号:121TS2 —骨替代物块10x5x5mm
产品编号:221TS1 —骨替代块20x10x10mm
(也提供双,三,四和演示包)
物品编号:321TS1 —骨替代圆柱体?20x15mm
商品编号:521TS2 —骨替代圆柱体?10x10mm
商品编号:521TS3 —骨替代圆柱体?12x10mm
商品编号:521TS4 —骨替代圆柱体?14x10mm
产品编号:521TS5 —骨替代圆柱体?16x10mm
物品编号:521TS6 —?18x10mm的骨替代圆柱
物品编号:521TS7 —?20x10mm的骨替代圆柱
物品编号:521TS8 —?22x10mm的骨替代圆柱
(也可作为双包和演示包使用)
货号:721TS1 —骨替代楔7x3x30x12mm
商品编号:721TS2 —骨替代楔10x3x30x12mm
商品编号:721TS3 —骨替代楔形物12x3x35x15mm
产品编号:721TS4 —骨替代楔形物15x3x35x15mm
(也可作为DEMO包提供)
Featured Publications
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3D Plotted Biphasic Bone Scaffolds for Growth Factor Delivery: Biological Characterization In Vitro and In Vivo. Ahlfeld T, Schuster FP, Foerster Y, Quade M, Akkineni AR, Rentsch C, Rammelt s, Lode A, Gelinsky M Advance Healthcare Materials 2019
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Bioprinting of mineralized constructs utilizing multichannel plotting of a self-setting calcium phosphate cement and a cell-laden bioink. Ahlfeld T, Doberenz F, Kilian D, Vater C, Korn P, Lauer G, Lode A, Gelinsky M Biofabrication 2018
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A Methylcellulose Hydrogel as Support for 3D Plotting of Complex Shaped Calcium Phosphate Scaffolds. Ahlfeld T, Koehler T, Czichy C, Lode A, Gelinsky M Gels 2018
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Strontium(II) and Mechanical Loading Additively Augment Bone Formation in Calcium Phosphate Scaffolds. Reitmaier S, Kovtun A, Schuelke J, Kanter B, Lemm M, Hoess A, Heinemann S, Nies B, Ignatius A Journal of Orthopaedic Research 2017
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In situ functionalization of scaffolds during extrusion-based 3D plotting using a piezoelectric nanoliter pipette. Giron S, Lode A, Gelinsky M Journal of 3D Printing in Medicine 2016
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3D plotting of growth factor loaded calcium phosphate cement scaffolds. Akkineni AR, Luo Y, Schumacher M, Nies B, Lode A, Gelinsky M Acta Biomaterialia 2015
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Medium-Term Funkction of a 3D Printed TCP/HA Structure as a New Osteoinductive Scaffold for Vertical Bone Augmentation: A Simulation by BMP-2 Activation. Moussa M, Carrel JP, Scherrer S, Cattani-Lorente M, Wiskott A, Durual S Materials 2015
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A 3D printed TCP/HA structure as a new osteoconductive scaffold for vertical bone augmentation. Carrel JP, Wiskott A, Moussa M, Rieder P, Scherrer S, Durual S Clinical Oral Implants Research 2014
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Fabrication of porous scaffolds by three-dimensional plotting of a pasty calcium phosphate bone cement under mild conditions. Lode A, Meissner K, Luo Y, Sonntag F, Glorius S, Nies B, Vater C, Despang F, Hanke T, Gelinsky M Journal of Tissue Engineering and Regenerative Medicine 2014
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Well-ordered biphasic calcium phosphate–alginate scaffolds fabricated by multi-channel 3D plotting under mild conditions. Lou Y, Lode A, Sonntag F, Nies B, Gelinsky M Journal of Materials Chemistry B 2013