Contrast-Enhanced Microtomographic Characterisation of Vessels in Native Bone and Engineered Vascularised Grafts Using Ink-Gelatin Perfusion and Phosphotungstic Acid

Objectives. Bone ischemia and necrosis are challenging to treat, requiring investigation of native and engineered bone revascularisation processes through advanced imaging techniques. This study demonstrates an experimental two-step method for precise bone and vessel analysis in native bones or vasc...

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Bibliographic Details
Published in:Contrast media and molecular imaging 2017-01, Vol.2017 (2017), p.1-10
Main Authors: Schaefer, D. J., Martin, Ivan, Scherberich, A., Schulz, Georg, Fulco, Ilario, Haumer, Alexander, Ismail, Tarek, Todorov, Atanas, Sutter, Sarah, Kaempfen, Alexandre
Format: Article
Language:English
Subjects:
Acids
Arteries
Biomedical materials
Blood vessels
Bone grafts
Bone growth
Bone imaging
Bones
Cylinders
Dimensional analysis
Gangrene
Gelatin
Grafting
Grafts
Hydroxyapatite
Imaging techniques
Ischemia
Laboratories
Medical imaging
Osteogenesis
Perfusion
Rats
Rodents
Substitute bone
Surgical implants
Tissue engineering
Veins & arteries
X ray microtomography
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Summary:Objectives. Bone ischemia and necrosis are challenging to treat, requiring investigation of native and engineered bone revascularisation processes through advanced imaging techniques. This study demonstrates an experimental two-step method for precise bone and vessel analysis in native bones or vascularised bone grafts using X-ray microtomography (μCT), without interfering with further histological processing. Methods. Distally ligated epigastric arteries or veins of 6 nude rats were inserted in central channels of porous hydroxyapatite cylinders and these pedicled grafts were implanted subcutaneously. One week later, the rats were perfused with ink-gelatin and euthanised and the femurs, tibias, and grafts were explanted. Samples were scanned using μCT, decalcified, incubated with phosphotungstic acid (PTA) for contrast enhancement, rescanned, and processed histologically. Results. Contrast-enhanced μCT displayed the course and branching of native bone vessels. Histologically, both central (−17%) and epiphyseal vessels (−58%) appeared smaller than in μCT scans. Hydroxyapatite cylinders were thoroughly vascularised but did not display bone formation. Grafts with a central artery had more (+58%) and smaller (−52%) vessel branches compared to grafts with a vein. Conclusions. We present a relatively inexpensive and easy-to-perform two-step method to analyse bone and vessels by μCT, suitable to assess a variety of bone-regenerative strategies.
ISSN:1555-4309
1555-4317
DOI:10.1155/2017/4035160