EFFECTS OF GRADED THERMAL-INJURY ON MICROVASCULAR PERMEABILITY AT THE SITE OF INJURY

To define whether capillary permeability traits at the site of a burn differ according to injury severity, a canine hind leg lymphatic was cannulated to measure macromolecular permeability in response to three different scalding solutions. Leg venous pressure was raised to approximate to 40 mm Hg and maintained until a minimal lymph-to-plasma total protein ratio (C-L/C-P)(min) and steady-state lymph flow (Q(L); mu l/min/100 g) was attained. The protein reflection coefficient (1 - C-L/C-P), fluid filtration coefficient (K-f; mu l/min/mm Hg/100 g), and Q(L) were determined before and for 6 hr after a B-sec hind paw immersion in either 100 degrees C (n = 7), 80 degrees C (n = 7), or 70 degrees C (n = 7) water. A group of five animals served as controls. In the absence of any systemic hemodynamic alterations, the 100 and 80 degrees C scald groups experienced significant (P < 0.05, ANOVA) increases in Q(L), C-L/C-P, and K-f as compared to respective preburn values and time-matched unburned control values. Most monitored parameters were significantly higher following 100 degrees C injury vs 80 degrees C injury. Parameters in the 70 degrees C group did change after scald, but were not significantly different from preburn values or from the control group. Alterations in capillary permeability to protein and fluid flux measured at the burn site are graded, not all or none phenomena, being dependent upon the severity of injury. (C) 1994 Academic Press, Inc.