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Bone Sialoprotein enhances Bone Regeneration
               https://doi.org/1016/j.bone.2009.09.007             https://doi.org/4161/biom.20921
           7.   Boudiffa M, Wade-Gueye NM, Guignandon A, et al., 2010,   18.  Motamedian SR, Hosseinpour S, Ahsaie MG, et al., 2015,
               Bone Sialoprotein Deficiency Impairs Osteoclastogenesis and   Smart Scaffolds in Bone Tissue Engineering: A Systematic
               Mineral Resorption In Vitro. J Bone Miner Res, 25:2669–79.  Review of Literature. World J Stem Cells, 7:657–68.
               https://doi.org/1002/jbmr.245                       https://doi.org/4252/wjsc.v7.i3.657
           8.   Malaval L, Wade-Gueye NM, Boudiffa M, et al., 2008, Bone   19.  Tye CE, Hunter GK, Goldberg HA, 2005, Identification of
               Sialoprotein Plays a Functional Role in Bone Formation and   the Type  I Collagen-binding  Domain  of Bone Sialoprotein
               Osteoclastogenesis. J Exp Med, 205:1145–53.         and Characterization of the Mechanism of Interaction. J Biol
               https://doi.org/1084/jem.20071294                   Chem., 280:13487–92.
           9.   Bouleftour W, Juignet L, Verdiere L, et al., 2019, Deletion      https://doi.org/1074/jbc.M408923200
               of  OPN in  BSP  Knockout  Mice  does not  Correct  Bone   20.  Wang  J,  Zhou  HY,  Salih  E, et  al.,  2006,  Site-specific  In
               Hypomineralization  but  Results  in High Bone  Turnover.   Vivo  Calcification  and  Osteogenesis  Stimulated  by  Bone
               Bone, 120:411–22.                                   Sialoprotein. Calcif Tissue Int, 79:179–89.
               https://doi.org/1016/j.bone.2018.12.001             https://doi.org/1007/s00223-006-0018-2
           10.  Holm E, Aubin JE, Hunter GK, et al., 2015, Loss of Bone   21.  Xu  L, Anderson AL,  Lu  Q,  et  al.,  2007,  Role  of  Fibrillar
               Sialoprotein  Leads  to  Impaired  Endochondral  Bone   Structure of Collagenous Carrier in Bone Sialoprotein-
               Development and Mineralization. Bone, 71:145–54.    mediated  Matrix  Mineralization  and  Osteoblast
               https://doi.org/1016/j.bone.2014.10.007             Differentiation. Biomaterials, 28:750–61.
           11.  Baranowski  A, Klein  A, Ritz U, et al.,  2016,  Surface      https://doi.org/1016/j.biomaterials.2006.09.022
               Functionalization  of Orthopedic  Titanium  Implants with   22.  Kruger  TE,  Miller AH,  Wang  J,  2013,  Collagen  Scaffolds
               Bone Sialoprotein. PLoS One, 11:e0153978.           in Bone  Sialoprotein-Mediated Bone  Regeneration.
               https://doi.org/1371/journal.pone.0153978           ScientificWorldJournal, 2013:812718.
           12.  Klein A, Baranowski A, Ritz U, et al., 2018, Effect of Bone      https://doi.org/1155/2013/812718
               Sialoprotein  Coated  Three-dimensional Printed Calcium   23.  Gorski JP, Franz NT, Pernoud D, et al., 2021, A Repeated
               Phosphate  Scaffolds  on  Primary  Human  Osteoblasts.   Triple  Lysine  Motif Anchors Complexes  Containing  Bone
               J Biomed Mater Res B Appl Biomater, 106:2565–75.    Sialoprotein and the type XI Collagen A1 Chain Involved in
               https://doi.org/1002/jbm.b.34073                    Bone Mineralization. J Biol Chem, 296:100436.
           13.  Gomes S, Gallego-Llamas J, Leonor IB, et al., 2013, In Vivo      https://doi.org/1016/j.jbc.2021.100436
               Biological  Responses  to Silk Proteins Functionalized  with   24.  Serra  T, Mateos-Timoneda  MA, Planell  JA, et al., 2013,
               Bone Sialoprotein. Macromol Biosci, 13:444–54.      3D  Printed  PLA-based  Scaffolds:  A  Versatile  Tool  in
               https://doi.org/1002/mabi.201200372                 Regenerative Medicine. Organogenesis, 9:239–44.
           14.  Baranowski A, Klein A, Ritz U, et al., 2018, Evaluation of      https://doi.org/4161/org.26048
               Bone Sialoprotein Coating of  Three-Dimensional  Printed   25.  Guvendiren  M,  Molde  J,  Soares  RM, et al.,  2016,  Designing
               Calcium Phosphate Scaffolds in a Calvarial Defect Model in   Biomaterials for 3D Printing. ACS Biomater Sci Eng, 2:1679–93.
               Mice. Materials (Basel), 11:2336.                   https://doi.org/1021/acsbiomaterials.6b00121
               https://doi.org/3390/ma11112336                 26.  Lauer A, Wolf P, Mehler D, et al., 2020, Biofabrication of
           15.  Klein A, Baranowski A, Ritz U, et al., 2020, Effect of Bone   SDF-1  Functionalized  3D-Printed  Cell-Free  Scaffolds  for
               Sialoprotein Coating on Progression of Bone Formation in a   Bone Tissue Regeneration. Int J Mol Sci, 21:2175.
               Femoral Defect Model in Rats. Eur J Trauma Emerg Surg,      https://doi.org/3390/ijms21062175
               46:277–86.                                      27.  Ritz U, Gerke R, Gotz H, et al., 2017, A New Bone Substitute
               https://doi.org/1007/s00068-019-01159-5             Developed from 3D-Prints of Polylactide (PLA) Loaded with
           16.  Wallace DG, Rosenblatt J, 2003, Collagen Gel Systems for   Collagen I: An In Vitro Study. Int J Mol Sci, 18:2569.
               Sustained Delivery and Tissue Engineering. Adv Drug Deliv      https://doi.org/3390/ijms18122569
               Rev, 55:1631–49.                                28.  Martin V, Ribeiro IA, Alves MM, et al., 2019, Engineering
           17.  Bierbaum   S,   Hintze   V,   Scharnweber   D,   2012,   a Multifunctional  3D-Printed PLA-collagen-minocycline-
               Functionalization  of  Biomaterial  Surfaces  Using  Artificial   nanoHydroxyapatite Scaffold with Combined Antimicrobial
               Extracellular Matrices. Biomatter, 2:132–41.        and  Osteogenic  Effects  for  Bone  Regeneration.  Mater Sci

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