In vivo analysis of the microcirculation of osteomyocutaneous flaps using fluorescence microscopy

Alendronate reduces periosteal microperfusion in vivo

Objectives

Bisphosphonates are known to induce a severe adverse effect known as medication-related osteonecrosis of the jaw (MRONJ). Previous studies have proven the impact of bisphosphonates on microperfusion; therefore, this study aimed to investigate alendronate-induced microcirculatory reactions in the calvarial periosteum of rats.

Study design

Bone chambers were implanted into 48 Lewis rats. Microhemodynamics, inflammatory parameters, functional capillary density and defect healing were examined after alendronate treatment for two and six weeks using repetitive intravital fluorescence microscopy for two weeks.

Results

Microhemodynamics remained unchanged. In alendronate-treated rats, inflammation was slightly increased, functional capillary density was significantly reduced (day 10: controls 100.45 ± 5.38 cm/cm2, two weeks alendronate treatment 44.77 ± 3.55 cm/cm2, six weeks alendronate treatment 27.54 ± 2.23 cm/cm2) and defect healing was decelerated. The changes in functional capillary density and defect healing were dose-dependent.

Conclusion

The bisphosphonate alendronate has a significant negative impact on periosteal microperfusion in vivo. This could be a promising target for the treatment of MRONJ.

Examination of Local Periosteal Microcirculation After Application of Absorbable and Nonabsorbable Membranes

The use of different membranes is common in dentoalveolar surgery. Absorbable and nonabsorbable membranes are used, often beneath the periosteum, to fulfil different functions (as barriers, patches, or spacers). It is still unclear to what extent such membranes affect the biology of the periosteum and what role is played by piezoelectric devices during preparation of the periosteum. We placed two different membranes (absorbable and nonabsorbable) underneath the periosteum of rat calvaria. We prepared the periosteum using different methods (piezoelectric device vs mechanical device). We then examined and analyzed periosteal microcirculation over a period of 28 days. A clear difference was observed between the two methods when used with absorbable membranes: The piezoelectric device offered advantages. Absorbable membranes maintain considerably more local periosteal microcirculation and should be given preference. In addition, we observed an advantage to using a piezoelectric device for periosteal dissection. Therefore, this method should also be used more widely.

Ischemic tissue injury in the dorsal skinfold chamber of the mouse: a skin flap model to investigate acute persistent ischemia

Despite profound expertise and advanced surgical techniques, ischemia-induced complications ranging from wound breakdown to extensive tissue necrosis are still occurring, particularly in reconstructive flap surgery. Multiple experimental flap models have been developed to analyze underlying causes and mechanisms and to investigate treatment strategies to prevent ischemic complications. The limiting factor of most models is the lacking possibility to directly and repetitively visualize microvascular architecture and hemodynamics. The goal of the protocol was to present a well-established mouse model affiliating these before mentioned lacking elements. Harder et al. have developed a model of a musculocutaneous flap with a random perfusion pattern that undergoes acute persistent ischemia and results in ~50% necrosis after 10 days if kept untreated. With the aid of intravital epi-fluorescence microscopy, this chamber model allows repetitive visualization of morphology and hemodynamics in different regions of interest over time. Associated processes such as apoptosis, inflammation, microvascular leakage and angiogenesis can be investigated and correlated to immunohistochemical and molecular protein assays. To date, the model has proven feasibility and reproducibility in several published experimental studies investigating the effect of pre-, peri- and postconditioning of ischemically challenged tissue.

Venous drainage in retrograde island flap: an experimental study using fluorescence tracing technique

The pathway of venous drainage in retrograde island flaps was investigated by fluorescence tracing technique using the saphenous fasciocutaneous flap in New Zealand White rabbits. Forty animals were allocated into four groups according to the different times at 30 minutes (I), 24 hours (II), 72 hours (III), and 7 days (IV) after the operation. According to the different routes to give tracer, each group was further allocated into two subgroups of the artery injection and vein injection. For each animal, one hindlimb was assigned as the experimental side, the contralateral side as control without giving tracer. The erythrocytes were separated, labeled with fluorescein isothiocyanate (FITC), detected, and injected into the artery or vein. Subsequently, the flaps were harvested 5 seconds after injection and immediately frozen, sectioned, and observed under microscope. In group I and II, the fluorescence was observed mainly around the vessel adventitia of the vein and artery and tunica intima of the artery. In group III, there was weak fluorescence observed in the lumen of vein. In group IV, fluorescence was distributed principally in the lumen of the vein. In addition, fluorescence was not observed in the saphenous nerve in group I and there was mild fluorescence in the saphenous nerve in groups II, III, and IV. These findings suggest that the venous return is through "bypass route" in earlier period. In later period, the venous retrograde return is through "bypass route" and "incompetent valves route;" however, "incompetent valves route" becomes the main route.

Effects of maleimide-polyethylene glycol-modified human hemoglobin (MP4) on tissue necrosis in SKH1-hr hairless mice

OBJECTIVE

Tissue hypoxia after blood loss, replantation and flap reperfusion remains a challenging task in surgery. Normovolemic hemodilution improves hemorheologic properties without increasing oxygen carrying capacity. Red blood cell transfusion is the current standard of treatment with its attendant risks. The aim of this study was to investigate the potential of the chemically modified hemoglobin, MP4, to reduce skin flap necrosis and its effect on selected blood markers and kidneys.

MATERIALS AND METHODS

Tissue ischemia was induced in the ear of hairless mice (n=26). Hemodilution was performed by replacing one third of blood volume with the similar amount of MP4, dextran, or blood. The extent of non-perfused tissue was assessed by intravital fluorescent microscopy.

RESULTS

Of all groups, MP4 showed the smallest area of no perfusion (in percentage of the ear +/- SEM: 16.3% +/- 2.4), the control group the largest (22.4% +/- 3.5). Leukocytes showed a significant increase in the MP4 and dextran group (from 8.7 to 13.6 respectively 15.4*109/l). On histology no changes of the kidneys could be observed.

CONCLUSION

MP4 causes an increase of leukocytes, improves the oxygen supply of the tissue and shows no evidence of renal impairment.

Reduction of midfacial periosteal perfusion failure by subperiosteal versus supraperiosteal dissection

PURPOSE

Detachment of soft tissue is a prerequisite for cleft repair. Recent experimental studies have indicated that supraperiosteal rather than subperiosteal soft tissue detachment causes midfacial hypoplasia, although, the cause has not been clarified yet. We hypothesized that microcirculatory dysfunction may be responsible for hypoplasia development, and established in rabbits an experimental model to study the differences in nutritive perfusion of midfacial periosteum in dependency on the applied technique of soft tissue detachment.

MATERIALS AND METHODS

In anesthetized New Zealand White rabbits a cranially broadly based rectangular soft tissue flap was intraorally circumcised on the anteromedial aspect of the maxilla. After either supraperiosteal or subperiosteal soft tissue detachment fluorescence microscopy allowed quantitative in vivo analysis of the nutritive perfusion of midfacial periosteum.

RESULTS

Microscopic analysis of individually perfused capillaries showed that blood flow was comparable in supraperiosteally and subperiosteally dissected maxillary periosteum. Nonetheless, both dissection techniques were associated with a remarkable capillary perfusion failure. However, the functional capillary density, which indicates the number of perfused capillaries per tissue area and thus the overall quality of capillary perfusion, was found significantly ( P < .05) lower in supraperiosteally than in subperiosteally dissected periosteum.

CONCLUSION

Using a new model for in vivo quantification of periosteal perfusion in the maxilla of rabbits, periosteal perfusion was found significantly more deteriorated after supraperiosteal compared with subperiosteal soft tissue detachment. The marked reduction of periosteal microcirculatory perfusion failure after subperiosteal soft tissue detachment may contribute to the clinically observed protection from manifestation of midfacial hypoplasia after cleft repair.

Improvement of nutritive perfusion after free tissue transfer by local heat shock-priming-induced preservation of capillary flowmotion

BACKGROUND

Capillary flowmotion protects pedicled flaps during critical perfusion conditions. However, free tissue transfer, causing ischemia-reperfusion and surgical trauma, have been shown to blunt these protective blood flow fluctuations. Because heat shock priming protects tissue after transfer, we herein studied whether heat shock protein expression is capable to preserve critical perfusion-induced capillary flowmotion in transferred composite flaps.

METHODS

In Sprague Dawley rats (n = 16), osteomyocutaneous flaps were subjected to critical perfusion after harvest and 1 h and 4 h after free transfer. In eight animals additional heat shock priming was induced 24 h before flap harvest. Microcirculation including capillary flowmotion was analyzed using intravital fluorescence microscopy.

RESULTS

After harvest, critical perfusion induced capillary flowmotion in skeletal muscle tissue of all flaps. By this, functional capillary density (FCD), an indicator of nutritive perfusion, was maintained not only in muscle but also in periosteum, subcutis, and skin. In contrast, 1 h after flap transfer muscle capillary flowmotion was completely abrogated, resulting in a significant decrease of FCD in all tissues. Heat shock-priming completely restored capillary flowmotion, and, by this, maintained tissue FCD.

CONCLUSIONS

The loss of muscle capillary flowmotion after free tissue transfer-associated ischemia-reperfusion can be prevented by heat shock-priming. This may represent the mechanism of protection by local heat application.

Evolution of ischemic tissue injury in a random pattern flap: A new mouse model using intravital microscopy

BACKGROUND

Dissection of random pattern flaps may cause microcirculatory dysfunction and ischemia, which jeopardize wound healing due to impaired tissue viability. The aim of this study was to develop an in vivo model that enables continuous monitoring of the interplay between microcirculatory dysfunction, ischemia, and tissue injury by intravital microscopy.

MATERIALS AND METHODS

A laterally based random pattern skin flap (15 x 11 mm) including the panniculus carnosus was raised in the back of mice and fixed into a dorsal skinfold chamber (n = 10). Arteriolar blood flow, functional capillary density, number of apoptotic cells, and area of tissue necrosis were analyzed by intravital fluorescence microscopy in the proximal, middle, and distal part of the flap at day 1, 3, 5, and 7 after surgery. Chamber preparations without flap harvesting served as controls (n = 6).

RESULTS

At day 1, the distal part of the flap showed a decreased arteriolar blood flow (266 +/- 124 pl/s versus controls: 1418 +/- 351 pl/s; P < 0.05), which resulted in severe alteration of functional capillary density (43 +/- 11 cm/cm2 versus 270 +/- 7 cm/cm2; P < 0.001). The impaired microcirculation was associated with apoptotic cell death (277 +/- 50 cells/mm2 versus 50 +/- 5 cells/mm2; P < 0.05). Microcirculatory dysfunction persisted over 7 days, and, finally, resulted in 49 +/- 3% flap necrosis.

CONCLUSIONS

This new model enables repetitive and simultaneous in vivo microscopic evaluation of microvascular hypoperfusion, apoptosis, and tissue necrosis in a random pattern flap. By the use of gene-targeted mice, it bears great potential to analyze distinct mechanisms of flap failure. It further represents an ideal tool to study novel protective strategies, including induction of angiogenesis, heat shock proteins, and HIF-1alpha.

New experimental composite flap model in rats: gluteus maximus-tensor fascia lata osteomuscle flap

Experimental animal models need to be developed for studies of composite flaps that have often recently been used for defects of both bone and soft tissues. A consistent anatomy, simple surgical technique, and reliable blood flow are essential for the success of experimental flap studies. Here we propose a gluteus maximus-tensor fascia lata osteomuscle flap in rats as a model of these qualities. Gluteus maximus and tensor fascia lata muscles and the adjacent iliac bone segment were combined as a lateral circumflex femoral artery-based flap. To test the reliability of this composite flap, three types of composite tissues were harvested and replaced: osteomusculocutaneous flap, osteomuscle flap, and osteomuscle composite graft. The osteomusculocutaneous flap was elevated by including a skin island over the gluteal region. The osteomuscle graft was formed by deliberately dividing the vascular pedicle of the osteomuscle flap. Direct observation revealed complete necrosis of the skin islands in all osteomusculocutaneous flaps. Microangiography of the flap demonstrated that both muscles and the attached bone were supplied by the pedicle. Dye studies with nitro blue tetrazolium (NBT) and India ink demonstrated dye uptake in both muscle and bone components in osteomuscle flaps. Histological examinations also demonstrated the viability of both tissues only in the flap group. Bone scintigraphy performed in flaps on postoperative day 7 demonstrated radionuclide uptake, confirming perfusion of the bony segment. The gluteus maximus-tensor fascia lata osteomuscle flap is a reliable and simple model for composite flap studies that offers the following advantages: 1) it is a new composite flap which includes bone, 2) it can be dissected easily with the naked eye, without using the microscope, 3) it has a long pedicle for flap displacement, and 4) it is a small animal model.

Modulating effects of L-arginine on cytokine-stimulated lymphocyte migration in vitro

Elective microsurgical transplants have become routine. Yet there remains a 1-5% rate of complete flap necrosis among these surgical reconstructions. This rate is much higher in emergent replantations. Despite technically accurate surgery, perfusion fails in this group. This lack of perfusion, or no-reflow, has been attributed to ischemic-reperfusion injury. The exact nature of this phenomenon remains poorly characterized, though it is clear that significant changes occur in such situations at the endothelial vascular interface. In an effort to understand the biomolecular events involved in ischemic-reperfusion injury we investigated the modulation of leukocyte transendothelial migration. Using a chemotactic chamber model with a cytokine stimulate mono-layer of umbilical vein endothelium, we evaluated the migration rate of peripheral blood mononuclear cells in the presence of exogenous L-arginine and/or the nitric oxide synthase inhibitor L-NAME. Levels of INF-gamma and TNF-alpha production were also determined. It was found that in the face of cytokine pre-stimulation and L-arginine, mononuclear cell trans-endothelial migration increased dramatically. There were also parallel increases in inflammatory cytokine output. These responses were sharply decreased by L-NAME. The results of this study suggest that in vitro nitric oxide augments transendothelial migration of inflammatory cells. Modulation of this response may provide a clinically useful method of minimizing ischemic-reperfusion injury.

Inhibition of nitric oxide synthase (NOS) conversion of L-arginine to nitric oxide (NO) decreases low density mononuclear cell (LD MNC) trans-endothelial migration and cytokine output

BACKGROUND

Biochemical, molecular, and cellular events at the micro-vascular endothelial interface determine the integrity of the vascular system. Disruption of these events has been described to occur in accordance with ischemic/reperfusion injury leading to inflammation, cell adhesion, and endothelial permeability changes. It has also been suggested that nitric oxide (NO) participates in these events. However, the manner in which it does is debated. The purpose of this study was to investigate the effects of exogenous L-arginine, an NO precursor, and L-N (G) nitroarginine methyl ester (L-NAME), a nitric oxide synthase (NOS) inhibitor, upon inflammatory events at the endothelial interface.

MATERIAL AND METHODS

Fresh cultures of human umbilical vein endothelial cells were established and used to seed Transwell chemotaxic chambers, and then grown to confluence. Whole blood was obtained from the same healthy volunteer and processed for light density mononuclear cells. Following per-stimulation of the endothelial monolayer with IL-1beta or antigen-antibody complex, known numbers of mononuclear cells were seeded to the endothelium. Incubation with and without exogenous L-arginine or L-NAME for 48 h was done. Lower chamber supernatant was then collected, cell numbers and viability determined and levels of inflammatory cytokines TNF-alpha and INF-lambda determined via ELISA assay.

RESULTS

Tran-endothelial cellular migration was nil lacking pre-stimulation, regardless of the addition of exogenous L-arginine. With pre-stimulation trans-endothelial migration increased significantly, a response that was greatly enhanced by L-arginine. With the further addition of L-NAME cellular migration decreased substantially. Pro-inflammatory cytokine levels of TNF-alpha and INF-lambda followed levels of cellular migration.

CONCLUSIONS

In vitro there was little to no trans-endothelial migration of inflammatory cells across an unstimulated monolayer of vascular endothelium. Pre-stimulation of the same endothelial monolayer with either a cytokine or antigen-antibody complex resulted in a significant trans-endothelial migration of inflammatory cells. This latter response was associated with a concurrent increase in the secretion of the pro-inflammatory cytokines TNF-alpha and INF-gamma. The presence of the NO precursor L-arginine greatly enhanced the observed inflammatory response. Conversely, L-NAME, an inhibitor of NOS, depressed the inflammatory response.

Protective skeletal muscle arteriolar vasomotion during critical perfusion conditions of osteomyocutaneous flaps is not mediated by nitric oxide and endothelins

BACKGROUND

After flap surgery, vasomotion, defined as oscillation of the arteriolar diameter, may protect tissue during critical perfusion conditions. The mechanisms that regulate vasomotion are still unclear; therefore, we studied the incidence of vasomotion in peripheral tissue and whether nitric oxide or endothelins are involved in regulation of vasomotion.

MATERIALS AND METHODS

In Sprague-Dawley rats, an osteomyocutaneous flap was prepared. To induce critical perfusion conditions, we reduced arterial blood flow supplying the flap to 0.15 ml/min. Seven animals received NG-nitro-L-arginine methyl ester (L-NAME), a nitric oxide-synthase inhibitor, and six animals bosentan, an endothelin A/B receptor antagonist. Microcirculation of muscle, skin, subcutis and periosteum was assessed by intravital microscopy before and after drug application.

RESULTS

In all animals, reduction of arterial blood supply induced arteriolar vasomotion in muscle (100%), but not in periosteum, subcutis and skin. Vasomotion was found to be affected by neither L-NAME (frequency 2.6+/-0.2 versus 2.4+/-0.2 cycles/min; amplitude 67+/-19 versus 55+/-20%; share of dilation period in vasomotion cycle 59+/-2 versus 58+/-3%) nor bosentan (1.8+/-0.1 versus 1.7+/-0.1 cycles/min; 60+/-10 versus 64+/-6%; 50+/-2 versus 53+/-1%).

CONCLUSIONS

Our study indicates that during critical perfusion conditions, arteriolar vasomotion develops only in muscle, not in skin, subcutis and periosteum, and that nitric oxide and endothelins are not involved in the regulation of this protective vascular response.

Microvascular transfer-related abrogation of capillary flow motion in critically reperfused composite flaps

Capillary flow motion is defined as rhythmic fluctuations of blood flow in the capillaries. Although critical perfusion has been demonstrated to induce capillary flow motion, little is known about the role of capillary flow motion in microvascular free flaps. The aim of this study was to elucidate the tissue-confined incidence and consequence of capillary flow motion in microvascularly transferred composite flaps, using intravital fluorescence microscopy. In Wistar rats, transferred osteomyocutaneous flaps (n = 7), which were exposed to 1 h of ischaemia during the anastomotic procedure followed by 1 h of reperfusion, were subjected to critical perfusion by stepwise reduction of the femoral-artery blood flow to 0.15 ml min(-1), 0.10 ml min(-1) and 0.05 ml min(-1). Pedicled osteomyocutaneous flaps that were not subjected to ischaemia (n=8) served as controls. In pedicled flaps critical perfusion induced capillary flow motion in the muscle, but not in the skin, subcutis and periosteum. In these flaps, the functional capillary density was preserved in all tissues analysed, including the skeletal muscle. Additional sympathetic denervation of the pedicled flaps did not change the incidence or pattern of capillary flow motion. In contrast, after flap transfer capillary flow motion in muscle tissue did not occur during critical perfusion. As a consequence, a shutdown of perfusion of individual capillaries was observed, resulting in a significant reduction (P<0.05) in functional capillary density, not only in the subcutis, skin and periosteum but also in the muscle itself. Thus, our data suggest that the microcirculatory control of pedicled osteomyocutaneous flaps is preserved during critical perfusion by skeletal-muscle capillary flow motion, whereas this protective regulatory mechanism is lost during the initial reperfusion period after flap transfer, probably not because of denervation but because of surgery- and/or ischaemia-reperfusion-associated injury.

A new flap model in rats: iliac osteomusculocutaneous flap

Although osteomusculocutaneous flaps are used frequently in clinical practice to repair defects involving soft tissue and bone, there are still many questions that remain to be answered regarding their basic physiology. To accomplish such basic science studies, simple and reliable animal osteomusculocutaneous flap models are needed. The purpose of this study was to describe a new flap model in rats--namely, the iliac osteomusculocutaneous flap. Thirty adult Wistar rats weighing 200 to 250 g were used in this experiment. In 15 rats, the vascular anatomy of the iliolumbar vessels and their relation with adjacent soft tissues and the iliac bone was determined by anatomic dissection. Based on this anatomic study, the iliac osteomusculocutaneous flap model was created in rats. The flap is comprised of a skin island (3 x 3 cm) in the flank region, a 1 x 1-cm segment of iliac bone, and an abdominal wall muscle cuff. In 10 rats, the flap was raised as an island flap based on its vascular pedicle of iliolumbar vessels, and was replaced in situ. In the remaining 5 rats, the flap was transferred to the groin region as a free flap. Direct observation on postoperative day 7 revealed that the skin island of all the flaps was completely viable. Bone scintigraphy performed on postoperative day 3 in free flaps demonstrated radionuclide uptake, indicating viability of the bony segment. The dye injection study revealed ink staining within blood vessels of the bone, confirming its viability. Microangiography of the flap demonstrated vascularity of each component of the flap by the iliolumbar vessels, including a distinct branch to the iliac bone. The authors conclude that the iliac osteomusculocutaneous flap of the rat is a simple and reliable flap model that offers the following advantages: (1) It is a true osteomusculocutaneous flap, (2) it can be used as a free flap without the need for an isogeneic rat, (3) the vascular pedicle is consistent, and (4) it is harvested from a small-animal species.