Use of 5-Aminolevulinic Acid to Assess Bone and Tissue Profusion in Orthopaedic Infection Patients

The focus of this study is to (1) Explore variability in distribution of 5-Aminolevulinic Acid (ALA) in bone and soft tissue infection (2) Evaluate the change in 5-ALA distribution from pre to post debridement (3) Preliminarily determine whether 5-ALA has the possibility predict infection / treatment failure

Infection following trauma is one of the most prevalent and challenging complications faced by orthopedic surgeons in both military and civilian populations, occurring after up to 60% of open bone fractures. Several factors specific to this trauma place patients at high risk for infectious complications, including: traumatized tissues, open contaminated fracture, soft tissue coverage issues, catabolic state due to poly-trauma, prolonged hospitalization with exposure to nosocomial bacteria, and presence of metallic implants8. Infection requires one or more unplanned surgical procedures and leads to prolonged morbidity, loss of function, and potential loss of limb1. Failed treatment for bone infection results in recurrent infection, requiring repeat surgical procedures in approximately 30% of patients.

Studies are currently being conducted to evaluate the utility of first window Indocyanine Green (ICG) to identify areas of deficient perfusion. This is based upon the concept deficient perfusion prevents delivery of antibiotics and endogenous immune cells to traumatized tissues. In the setting of established infection, poorly perfused bone can be a nidus for biofilm formation creating resistance to antibiotics. However, in the context of this work it is becoming increasingly clear that acute (rather than chronic) infections display hyper vascularity with increased blood flow and neovascularization. Infection is known to display the enhanced permeability and retention effect with increased vascular permeability.

There are currently no accepted intraoperative tools that can be used to make objective decisions about which bone and tissue is infected and which is normal. Methods currently used to guide debridement are quite rudimentary. Clinical judgement is based on the gross appearance of soft tissue and bone, including color, turgor, and extent of soft tissue stripping. A burr may be used to look for bleeding bone. More extensive debridement is thought to minimize risk of index infection or reduce the rate of persistent infection; however, this comes at the cost of increasingly complex reconstructive procedures to fill bony defects. Clearly what is needed is a functional imaging system which can identify infected tissues to guide surgeons in the amount of tissue to debride. In turn, this will lead to fewer infections and a more effective treatment of surgical site infections (SSIs) at the fracture site. Both scenarios will allow patients to return to duty or work sooner.