Kinetics of blood flow during healing of excisional full-thickness skin wounds in pigs as monitored by laser speckle perfusion imaging

Background/purpose: The laser speckle perfusion imaging (LSPI) system is a new, non‐invasive technique for rapidly and reproducibly measuring tissue perfusion. The high resolution and frame rate of the LSPI overcome many of the limitations of traditional laser Doppler imaging techniques. Therefore,...

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Bibliographic Details
Published in:Skin research and technology 2006-11, Vol.12 (4), p.247-253
Main Authors: Stewart, C. J., Gallant-Behm, C. L., Forrester, K., Tulip, J., Hart, D. A., Bray, R. C.
Format: Article
Language:English
Subjects:
Animals
blood flow
Equipment Design
Female
Kinetics
laser speckle perfusion imaging (LSPI)
Lasers
porcine model
Regional Blood Flow
Rheology - instrumentation
Rheology - methods
Skin - blood supply
Skin - injuries
Swine
Time Factors
Wound Healing
Wounds, Penetrating - metabolism
Wounds, Penetrating - physiopathology
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Summary:Background/purpose: The laser speckle perfusion imaging (LSPI) system is a new, non‐invasive technique for rapidly and reproducibly measuring tissue perfusion. The high resolution and frame rate of the LSPI overcome many of the limitations of traditional laser Doppler imaging techniques. Therefore, LSPI is a useful means for evaluating blood flow in a variety of situations. The present study investigates the ability of the LSPI system to detect temporal changes in blood flow during the healing of cutaneous wounds in a well‐characterized animal model. Methods: Full‐thickness excisional skin wounds (2 × 2 cm) were created on the backs of juvenile female red Duroc pigs. Every week post‐injury, the wounds were measured and photographed, and normalized blood flow values were determined using the LSPI system. Results: Tissue perfusion values were available after complete re‐epithelialization and removal of the eschar, at day 21. At this point, wound blood flow was significantly elevated as compared with the surrounding, uninvolved skin. Wound blood flow declined steadily during healing, and approached normal values by day 35 post‐injury. Conclusion: The kinetics of blood flow during excisional wound healing in the red Duroc model are comparable with that previously observed in laser Doppler imaging of healing human skin wounds and hypertrophic scars. These results therefore confirm that the red Duroc is a good model of human wound healing, and further indicates that the LSPI is an excellent technique for evaluating angiogenesis and neovascularization during healing in this and other models.
ISSN:0909-752X
1600-0846
DOI:10.1111/j.0909-752X.2006.00157.x