CAR (CARSKNKDC) is a systemically administered wound-homing peptide that specifically recognizes angiogenic blood vessels and extravasates into sites of injury. CAR peptide requires heparan sulfate proteoglycans (HSPGs) for its cell penetrating activity. Syndecan-4 (SDC4) is a HSPG and binding to it triggers the wound re-epithelialization process. We have discovered that CAR peptide has the inherent ability to promote wound healing; wounds close and re-epithelialize significantly faster in CAR treated mice than in control groups (PBS and mutant peptide, i.e. mCAR injections). To delineate the molecular mechanism by which CAR accelerates wound healing, we focused on the requirement of HSPG binding for CAR peptide function. We demonstrate that CAR peptide endocytosis and its stimulation of keratinocyte cell migration are both dependent on SDC4. Finally, we show that the systemic administration of CAR peptide stimulates wound re-epithelialization only in WT mice, but not in SDC4 knockout (KO) mice. As SDC4 has very restricted expression in skin wounds, we propose that CAR peptide activates SDC4 function to promote re-epithelialization. CAR peptide may provide an entirely new way of enhancing wound healing, and perhaps tissue regeneration in general. This therapeutic approach is systemic, yet target organ- and cell- specific, and dependent on the naturally occurring SDC4 dependent migratory pathway that is crucial for tissue regeneration.

Aims: Serial dilation of the walls of the bone tunnel has been advocated to provide more dense bone-tunnel walls and optimal conditions for rigid fixation in anterior cruciate ligament (ACL) reconstruction with soft tissue grafts. The aim of this study was to compare the initial fixation strength obtained using serial dilation versus conventional extraction drilling in ACL reconstruction. Methods: Initial strength of doubled anterior tibialis tendon grafts fixed with bioabsorbable interference screw was assessed in 21 pairs of human cadaver tibiae. Bone tunnels were created with either serial dilation or conventional extraction drilling (cannulated drill bits). The specimens were subjected to a cyclic-loading test (1500 loading cycles between 50 and 200 N at 0.5 Hz frequency). The specimens surviving the cyclic-loading test were loaded to failure at a rate of 1.0 m/min (single-cycle load-to-failure test). Results: During the cyclic-loading test, no significant stiffness or displacement differences were observed between the two bone-tunnel techniques. Three specimens failed in the serial-dilation group, while there were six failures in the extraction-drilling group. In the subsequent single-cycle load-to-failure test, the average yield load was 473 ± 110 N for the serial-dilation group and 480 ± 115 N for the extraction-drilling group (P=0.97). No significant difference between the two bone-tunnel techniques was found with regard to stiffness nor mode of failure. Conclusions: Serial dilation of the bone-tunnel walls does not increase the initial fixation strength of soft tissue grafts in ACL reconstruction.