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Friday, March 24, 2017
Multidisciplinary team publishes the first study of terahertz imaging based assessment of tissue flap viability
An interdisciplinary collaboration between the UCLA school of engineering and the UCLA school of medicine has produced the first published work describing the assessment of tissue flap viability using terahertz (THz) imaging. The research was led by Professor Taylor and postdoctoral scholar Neha Bajwa in the department of Bioengineering and Professor Maie St. John in the department of Head and Neck Surgery.
Tissue flaps have become a life-saving reconstructive option for patients with breast cancer, head and neck cancer, soft tissue defects, and wounds. A flap includes the harvested skin, muscle, soft tissue or bone, and their corresponding neurovascular supply. This tissue is either surgically resected and rotated or transferred from a donor site to a recipient site. In any flap surgery, the key for flap survival is to maintain or successfully reestablish the blood supply to the flap. Despite the high success rates of flap surgery, a small risk of vascular compromise can lead to devastating consequences and, therefore, necessitates urgent re-exploration for attempted salvage. Early and accurate assessment of flap viability – the most significant predictor of flap salvage outcome – is still an unmet clinical need.
The current gold standard for determining flap viability is clinical examination, in which skin color, capillary refill, turgor, and bleeding patterns are periodically examined. This method, however, is highly operator-dependent, and changes in the appearance of the flap due to microvascular complications are generally delayed by 1 to 2 hours, thus preventing early intervention. Efforts towards achieving more non-invasive and accurate tissue viability measurements have been widespread and include the use of several adjunctive optical technologies such as Laser Doppler Imaging (LDI) and fluorescence angiography. Adoption of these systems in surgical flap assessment have been hampered by a range of clinical constraints. In the case of LDI, the buildup of significant tissue edema (tissue water content (TWC)) immediately following tissue transplantation prevents the early stage acquisition of data needed to predict flap viability.
In this work, the group investigated the utility of tissue water content (TWC) based contrast in terahertz (THz) imaging for early assessment of flap viability. We obtained longitudinal visible and reflective THz imagery comparing 3 bipedicled flaps (i.e. survival model) and 3 fully excised flaps (i.e. failure model) in the dorsal skin of rats over a postoperative period of 7 days. While visual differences between both models manifested 48 hr after surgery, statistically significant (p < 0.05, independent t-test) local differences in TWC contrast were evident in THz flap image sets as early as 24 hr. Excised flaps, histologically confirmed as necrotic, demonstrated a significant, yet localized, reduction in TWC in the flap region compared to non-traumatized skin. In contrast, bipedicled flaps, histologically verified as viable, displayed mostly uniform, unperturbed TWC across the flap tissue. These results indicate the practical potential of THz TWC sensing to accurately predict flap failure 24 hours earlier than clinical examination