Perfusion Controlled Mobilization after Lower Extremity Free Flaps-Pushing the Limits of Time and Intensity.

Background The current standard to gradually adapt the fragile perfusion in lower extremity free flaps to an upright posture is the dangling maneuver. This type of flap training neither fits the orthostatic target load of an upright posture, nor does it assist in mobilizing the patients effectively. In this study, we quantitatively analyzed training effects of an early and full mobilization on flap perfusion. Methods A total of 15 patients with gracilis flaps for distal lower extremity reconstruction were included. Flap training was performed daily by mobilizing the patients on a tilt table into a fully upright posture for 5 minutes between the third and fifth postop days (PODs). Changes in micro- and macrocirculation were analyzed by laser Doppler flowmetry, remission spectroscopy, and an implanted Doppler probe. Results All flaps healed without complications. Yet, in three patients, the increased orthostatic load required an adjustment of the training duration due to a critical blood flow. The others showed an increasing compensation in the microcirculation. When tilting the patients, blood flow and oxygen saturation dropped significantly less on POD5 than on POD3. Furthermore, a significant increase of the blood flow was noted after an initial decrease during the mobilization on all days. An increasing compensation in the macrocirculation could not be determined. Conclusion Full mobilization of patients with lower extremity free flaps can be performed safely under perfusion monitoring, already starting on POD3. Additionally, monitoring allows a consideration of the individual orthostatic competence and therefore, exploitation of the maximum mobilization potential.

Nanocoating with titanium reduces iC3b- and granulocyte-activating immune response against glutaraldehyde-fixed bovine pericardium: a new technique to improve biologic heart valve prosthesis durability?

OBJECTIVES: An IgG and granulocyte-activating immune response with secondary dystrophic calcification might be the reason glutaraldehyde (GA)-fixed xenograft valves fail, especially in young patients, who are more immunocompetent than the elderly. Titanium nanocoating on GA-fixed bovine pericardium was tested for its ability to prevent major immunoreactions. METHODS: The immune activity of platelets from GA-fixed bovine pericardium with different treatment procedures was evaluated using the blood from 5 human donors: group I (n = 5), GA fixed as the control; group 2 (n = 5), detoxified with 10% citric acid; group 3 (n = 5), 10% citric acid, aldehyde-dehydrogenase, and a physical plasma treatment; and group 4 (n = 5), treated the same as group 3, but with an additional titanium coat 30 nm in thickness. Titanium deposition was visualized using scanning electron microscopy. IgG deposits (iC3b) were shown by immunostaining and documented as colored pixels (red). The pixels were evaluated electronically. Attracted granulocytes (polymorphonuclear leukocytes) were counted in front of the titanium-coated surface. RESULTS: IC3b deposits and polymorphonuclear leukocytes within control group 1 were defined as 100%; in group 2, iC3b was 149% ± 34% and polymorphonuclear leukocytes were 89%, in group 3, IC3b was 102% ± 24% and polymorphonuclear leukocytes were 47%; and in group 4, IC3b had decreased to 38.49% ± 21% (P < .05) and polymorphonuclear leukocyte activation had decreased to 6.3% (P ≤ .01). CONCLUSIONS: Titanium coating significantly reduced the iC3b and granulocyte activating immune response of GA-fixed pericardium. Therefore, it might prevent relevant immunorejection and increase the durability of GA-fixed bioprosthetic heart valves.

Detoxification and endothelialization of glutaraldehyde-fixed bovine pericardium with titanium coating: a new technology for cardiovascular tissue engineering.

BACKGROUND: Endothelial cell seeding of glutardialdehyde-fixed biological heart valves is hypothesized to improve biocompatibility and durability; however, the toxicity of glutardialdehyde prevents its use as a biological coating. Therefore, different detoxification strategies are applied, including surface coating with titanium, before in vitro endothelialization of glutaraldehyde-fixed bovine pericardium as the base material for prosthetic heart valves. METHODS AND RESULTS: Bovine pericardium was fixed with 0.25% glutardialdehyde. Detoxification was performed with citric acid, aldehyde dehydrogenase, and plasma deposition with titanium at low temperatures of 30 degrees C to 35 degrees C. Toxic glutaraldehyde ligands were quantified photometrically, and the vitality of seeded cells was tested to validate detoxification methods. Detoxification agents and titanium coating were applied before seeding with human endothelial cells. Endothelial cells were visualized by electron microscopic surface scanning. To evaluate cell adhesion, shear stress was applied by a flow of 5 L/min over 24 hours. Compared with untreated glutaraldehyde-fixed samples, treatment with the different agents reduced free aldehyde groups gradually (citric acid 5% < citric acid 10% < titanium < aldehyde dehydrogenase). A combination of citric acid 10%, aldehyde dehydrogenase, and titanium coating resulted in a reduction of free aldehyde ligands to 17.3+/-4.6% (P < or = 0.05) and demonstrated a vitality of seeded cells of 94+/-6.7% (P < or = 0.05). This procedure yielded a completely confluent layer of regular human endothelial cells (n=5). After application of shear stress for 24 hours on these endothelial layers, cell vitality was 81%. CONCLUSIONS: Titanium coating combined with chemical procedures yielded significant detoxification and complete endothelialization of conventional glutaraldehyde-fixed pericardium. This new technique might improve glutardialdehyde-fixed cardiovascular bioimplants for better biocompatibility and longer durability.