De novo Generation of an Axially Vascularized Processed Bovine Cancellous-Bone Substitute in the Sheep Arteriovenous-Loop Model

Abstract Background The aim of this study was to compare new bone formation, resorbed bone matrix, and fibrous enclosed residual bone substitute material in laterally augmented alveolar bone defects using allogeneic, pre-treated and cleaned human bone blocks (tested in dogs, therefore considered to be xenogeneic), and pre-treated and cleaned bovine cancellous bone blocks, both with and without a collagen membrane in order to evaluate their augmentative potential. Methods Thirty-two critical size horizontal defects were prepared in the mandible of 4 adult foxhound dogs (8 per dog, 4 on each side). After 3 months of healing, the defects were laterally augmented in a split-mouth-design with either human (HXB) or bovine solvent-preserved bone blocks (BXB). Afterwards, defects were randomly covered with a bovine collagenous membrane (HXB + M, BXB + M). After a healing interval of 6 months, percentages of new bone formation, resorbed bone matrix, and fibrous enclosed residual bone substitute material were compared. Results Results showed little new bone formation of up to 3.7 % in human bone blocks (HXB 3.7 % ± 10.2, HXB + M 0.3 %± 0.4, BXB, 0.1 % ± 0.8, BXB + M 2.6 % ± 3.2, p = > 0.05). Percentages of fibrous encapsulation were higher in human bone blocks than in bovine bone blocks (HXB 71.2 % ± 8.6, HXB + M 73.71 % ± 10.6, BXB, 60.5 % ± 27.4, BXB + M 52.5 % ± 28.4, p = > 0.05). Resorption rates differed from 44.8 % in bovine bone blocks covered with a membrane to 17.4 % in human bone blocks (HXB 17.4 % ± 7.4, HXB + M 25.9 % ± 10.7, BXB, 38.4 % ± 27.2, BXB + M 44.8 % ± 29.6, p = > 0.05). The use of additional membranes did not significantly affect results. Conclusions Within its limitations, results of this study suggest that solvent-preserved xenogenic human and bovine bone blocks are not suitable for lateral bone augmentation in dogs. Furthermore, defect coverage with a membrane does not positively affect the outcome.

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Human Umbilical Vein Endothelial Cell Support Bone Formation of Adipose-Derived Stem Cell-Loaded and 3D-Printed Osteogenic Matrices in the Arteriovenous Loop Model

Tissue Engineering Part A ◽

10.1089/ten.tea.2020.0087 ◽

2020 ◽

Cited By ~ 1

Author(s):

Sophie Winkler ◽

Hilkea Mutschall ◽

Jonas Biggemann ◽

Tobias Fey ◽

Peter Greil ◽

...

Keyword(s):

Stem Cell ◽

Endothelial Cell ◽

Bone Formation ◽

Umbilical Vein ◽

Loop Model ◽

Human Umbilical Vein ◽

3D Printed ◽

Adipose Derived Stem Cell ◽

Arteriovenous Loop ◽

Cell Support

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Tissue Engineering of Lymphatic Vasculature in the Arteriovenous Loop Model of the Rat

Tissue Engineering Part A ◽

10.1089/ten.tea.2020.0108 ◽

2020 ◽

Author(s):

Jan W. Robering ◽

Majida Al-Abboodi ◽

Adriana Titzmann ◽

Inge Horn ◽

Justus P. Beier ◽

...

Keyword(s):

Tissue Engineering ◽

Loop Model ◽

Lymphatic Vasculature ◽

Arteriovenous Loop

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Comparison of PLGA Reinforcement Method for Carbonate Apatite Foam

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.529-530.417 ◽

2012 ◽

Vol 529-530 ◽

pp. 417-420 ◽

Cited By ~ 1

Author(s):

Girlie M. Munar ◽

Melvin L. Munar ◽

Kanji Tsuru ◽

Ishikawa Kunio

Keyword(s):

Compressive Strength ◽

Porous Structure ◽

Cancellous Bone ◽

Bone Substitute ◽

Vacuum Infiltration ◽

Carbonate Apatite ◽

Potential Candidate ◽

Bone Substitute Material ◽

Substitute Material ◽

Scanning Electron

Carbonate apatite (CO3Ap) foam with interconnecting porous structure is a potential candidate as bone substitute material owing to its similarity to the cancellous bone with respect to composition, morphology and osteoclastic degradation. However, it is brittle and difficult to handle. This is thought to be caused by no organic material in the CO3Ap foam. The aim of this study is to reinforce the CO3Ap foam with poly (DL-lactide-co-glycolide) (PLGA). Immersion and vacuum infiltration methods were compared as reinforcing methods. Compressive strength of unreinforced CO3Ap foam, (12.0 ± 4.9 kPa) increased after PLGA reinforcement by immersion (187.6 ± 57.6 kPa) or by vacuum infiltration (407 ± 111.4 kPa). Scanning electron microscopy (SEM) showed the preservation of full interconnecting porous structure of CO3Ap foam after PLGA reinforcement using immersion or vacuum infiltration. Interface between the PLGA and CO3Ap foam, however revealed that no gap was found between the PLGA and CO3Ap foam interface when vacuum was used to reinforce the PLGA whereas a gap was found when simple immersion was used. Strong interface between PLGA and CO3Ap foam is therefore thought to be the key for higher compressive strength. In conclusion, vacuum infiltration is a more efficient method to reinforce the CO3Ap foam with PLGA for improving the mechanical strength without sacrificing the cancellous bone-type morphology.

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