Tubo-ovarian transplantation in the treatment of sterility. Experimental research]

Microsurgical transposition of fallopian tube and ovary has the potential of being an efficient therapeutic treatment in patients with tubal sterility. The Authors present their experience of microsurgical adnexal transplantation in rabbit by two different techniques: the first procedure by microvascular anastomosis of the ovarian vessels, the second one without vascular pedicle. Function is evaluated at various time after grafting by: exploratory laparotomy on day 30 to establish whether circulation to the grafts was still maintained; macroscopic and microscopic examination of ovaries and fallopian tubes. The microvascular techniques prove highly reliable in terms of immediate vascular patency rate but it is disappointing that 50% of the autografts has failed with blocked vessels by day 30. Perhaps this is due to the difficult techniques in anastomosing the ovarian vessels of small caliber. In spite of these outcomes the vascularized autografts were viable and functional after transplantation in contrast with the non-vascularized tubo-ovarian grafts which all failed. This experience encourages to believe that the microsurgical technique could be employed for homograft transplantation in woman with extensive ovarian and tubal damages.     

Folded free vascularized fibula transfer

A technique of improved free vascularized fibula grafting for bone defects up to 15 cm in length is presented with three illustrative cases. By dividing a harvested free fibula graft at its midpoint without dividing its vascular pedicle, two vascularized bone lengths are produced that require only one set of anastomoses. This folded fibula provides twice the cross-sectional area of a single fibula transfer and allows biomechanically improved graft placement. This technique has been successfully used in long bone defects of the upper and lower limbs.     

Flap prefabrication in the head and neck: a 10-year experience

Tissue neovascularized by implanting a vascular pedicle can be transferred as a "prefabricated flap" based on the blood flow through the implanted pedicle. This technique potentially allows any defined tissue volume to be transferred to any specified recipient site, greatly expanding the armamentarium of reconstructive options. During the past 10 years, 17 flaps were prefabricated and 15 flaps were transferred successfully in 12 patients. Tissue expanders were used as an aid in 11 flaps. Seven flaps were prefabricated at a distant site and later transferred using microsurgical techniques. Ten flaps were prefabricated near the recipient site by either transposition of a local vascular pedicle or the microvascular transfer of a distant vascular pedicle. The prefabricated flaps were subsequently transferred as island pedicle flaps. These local vascular pedicles can be re-used to transfer additional neovascularized tissues. Common pedicles used for neovascularization included the descending branch of the lateral femoral circumflex, superficial temporal, radial, and thoracodorsal pedicles. Most flaps developed transient venous congestion that resolved in 36 to 48 hours. Venous congestion could be reduced by incorporating a native superficial vein into the design of the flap or by extending the prefabrication time from 6 weeks to several months. Placing a Gore-Tex sleeve around the proximal pedicle allowed for much easier pedicle dissection at the time of transfer. Prefabricated flaps allow the transfer of moderate-sized units of thin tissue to recipient sites throughout the body. They have been particularly useful in patients recovering from extensive burn injury on whom thin donor sites are limited.     

Posterior interosseous free flap with extended pedicle for hand reconstruction

The anatomy of the posterior interosseous vessels makes them suitable as a donor area of free flap. The skin island can be designed on the perforating vessels of the distal third of the forearm, up to the dorsal wrist crease, to increase the pedicle length (7 to 9 cm). A series of nine flaps transferred to reconstruct hand defects is presented. All flaps were designed over the dorsal distal forearm, and dimensions permitted direct closure of the donor site (up to 4 to 5 cm wide). Apart from a linear scar, donor morbidity was negligible. All transfers were successful. Although its dissection is somewhat tedious, the anatomy of the vascular pedicle is suitable for microanastomosis and the skin island is thin, although hairy. The posterior interosseous free flap with extended pedicle may be a good choice when limited amounts of thin skin and a long vascular pedicle are needed.     

A combined rectus abdominis musculocutaneous flap and vascularized iliac bone graft with double vascular pedicles

Although a free vascularized iliac bone graft has been successfully used for the reconstruction of large bone defects, there is a serious problem of how to repair in one stage patients having a large bone defect with a very wide skin defect. A free combined rectus abdominis musculocutaneous flap and vascularized iliac bone graft with double vascular pedicles seems to be one of the most suitable methods for patients having large defects of both bone and skin. Based on our patient, the main advantage of this flap is the extreme width of the skin territory. The pedicle vessels are large and long, and the donor scar can be made in an unexposed area. This flap should be considered for use in one-stage reconstructions of large defects of both bone and skin in the leg region.     

Flap perfusion after free musculocutaneous tissue transfer: the impact of postoperative complications

In a previous study, the authors found persistence of pedicle blood flow up to 10 years after uncomplicated free latissimus dorsi transfer. In this study, the impact of postoperative complications (hematoma, thrombosis, infection) and successful surgical revision was tested. Since 1982, more than 1200 free tissue transfers have been performed at the authors' institution (Hannover Medical School). Of these, the authors selected two groups of 30 patients each who had received a free latissimus dorsi transfer to the lower leg without microsurgical nerve coaptation for wound coverage. All patients included in this study were carefully selected for clinical homogeneity, with one difference: group I comprised patients who had no postoperative complications after free latissimus dorsi transfer. Group II included only patients with major postoperative complications after the procedure. All flaps in group II survived after successful surgical revision. The arteries, which nourished the lower leg, were visualized and documented by means of a duplex scanner in both groups. Three different time intervals were chosen for measurements of blood flow: 4 to 6 months (groups I.I and II.I), 4 to 6 years (groups I.II and II.II), and 8 to 10 years (groups I.III and II.III). Quantitative measurements of local flap perfusion in milliliters per minute per 100 g tissue were performed by means of the hydrogen clearance technique. In each patient, a total of nine measurements was performed in three phases: phase A, before closing the vascular pedicle by manual compression (n = 3); phase B, with a closed pedicle (n = 3); and phase C, after releasing the vascular pedicle from manual compression (n = 3). Each measurement took approximately 10 minutes. One hundred percent closure of each pedicle in phase B was confirmed by the duplex scanner. Furthermore, all patients were monitored both clinically and by means of the hydrogen clearance technique during phase B for adequate blood supply to the lower leg. Lower leg perfusion showed no statistical differences for phases A, B, and C in all groups of patients. In group I, no statistical differences in local flap perfusion were encountered for phases A and C. In phase B, however, a statistically significant (p < 0.01) complete extinction of local flap perfusion was registered in all patients of group I at the site of the flap's skin paddle. In group II, however, persistent flap perfusion was registered during phase B in up to 50 percent of cases in one subgroup (II.III). No statistically significant alterations of local blood flow were registered in the surrounding tissue of group II during phases A, B, and C. Patients with thrombosis of the venous anastomosis (n = 7) seemed to have the highest incidence of loss of autonomous blood supply through the vascular pedicle (5 out of 11 cases). No inconstant results were found during the repetitive measurements (n = 3) for each patient in each phase. After uncomplicated free tissue transfer, the flap's intact vascular pedicle seems to play an important role in permanent flap survival up to 10 years after the procedure. Postoperative complications after free tissue transfer with successful surgical revision, especially venous thrombosis of the vascular anastomosis, may lead to loss of vascular flap autonomy over time.     

Deltopectoral skin flap as a free skin flap revisited: further refinement in flap design, fabrication, and clinical usage

The deltopectoral skin flap is an axial flap; therefore, it can be fashioned as a free skin flap. Although color and texture of the skin are well suited for facial resurfacing, the structural features of inconsistent thickness of the skin, a short vascular pedicle, a minute caliber of the nutrient vessel, and donor site morbidity often preclude the use of this flap for this purpose. The deltopectoral skin flap fabricated as a free skin flap transferred by means of a microsurgical technique was used in 27 patients between 1985 and 1998 at our hospital. The anterior perforating branches of the internal mammary vessels were the primary nutrient vessels of the flap in seven instances. The external caliber of this artery varied between 0.6 mm and 1.2 mm, with an average size of 0.9 mm. The size of the accompanying vein varied between 1.5 mm and 3.2 mm, with an average of 2.3 mm. Coaptation of these vessels with those in the recipient site was technically difficult. Thrombosis occurred at the anastomotic site in three patients, requiring reoperation. Two flaps were saved. The flap failure was drastically reduced in the remaining 20 patients by including a segment of the internal mammary vessel when fabricating the vascular pedicle. The size of the internal mammary arterial segment averaged 2.1 mm, and the average size of the accompanying vein was 2.9 mm. The problem of a bulky flap was managed by surgical defatting/thinning of the flap at the time of flap fabrication and transfer. A V-to-Y skin flap advancement technique of wound closure was used in eight individuals. The flap donor-site morbidities were minimized with this method of wound closure.     

Free omental tissue transfer for extremity coverage and revascularization

Microvascular transfer of the omentum has several unique advantages for the reconstruction and revascularization of extremity wounds. The omentum provides well-vascularized, malleable tissue for reconstruction of extensive soft-tissue defects and has a long vascular pedicle (35 to 40 cm) with sizable vessels, which reduces some of the potential technical challenges of microsurgery. It can also be used for flow-through revascularization of ischemic distal extremities. The unique properties of the omentum make it an ideal tissue for the reconstruction of difficult extremity defects, allowing simultaneous reconstruction and revascularization. Experience with six free omental tissue transfers for upper-extremity and lower-extremity reconstruction is described. Three of the cases involved distal anastomoses to take advantage of the flow-through characteristics of the flap, providing distal arterial augmentation. All flaps accomplished the reconstructive goals of wound coverage and extremity revascularization. The omentum is a valuable, often overlooked tissue for the treatment of difficult extremity wounds.     

The forearm flap

We present our experimental and clinical experiences with the free neurovascular forearm flap. The flap is based on the radial artery, one of the great veins of the forearm (cephalic, basilic, or interconnecting vein), and one or two cutaneous forearm nerves (ulnar, median, or lateral). Because of the standard anatomy, the large caliber of blood vessels, the good sensory supply, the quality and quantity of the forearm skin, and the thin layer of subcutaneous fat, the free forearm flap is a technically easy and safe flap for reconstruction of soft-tissue defects, especially those in the head and neck and those areas of the extremities where sensitive skin is desired.     

The parascapular flap for treatment of lower extremity disorders

The parascapular flap was used as a free microvascular transfer for soft-tissue resurfacing of 11 lower extremities. The diagnoses included four cases of osteomyelitis, three cases of vascular ulceration, one case of combined osteomyelitis and vascular ulceration, two cases of posttraumatic heel defects, and one case of extensive soft-tissue contracture overlying a posttraumatic defect of the femur. All cases were successful clinically. Anatomically, the parascapular flap is supplied by the cutaneous parascapular artery, a branch of the circumflex scapular artery, which itself derives from the subscapular artery. Flap territory may reach 15 x 30 cm, and the vascular pedicle can extend 14 cm if the subscapular artery is taken. Advantages of this flap include the constancy, length, and caliber of the vascular pedicle; the length and width attributes, which allow both coverage of large wounds and primary closure of the donor defect; and an absence of disruption of musculoskeletal function.     

The use of subcutaneous pedicle flaps in the treatment of postburn scar contractures

Subcutaneous pedicle flaps, which were usually applied to repair small skin defects in the face or the fingertip, have been used with success in the treatment of 17 postburn scar contractures, with the exception of one partial flap necrosis. The results indicate the reliability and usefulness of this technique in the treatment of scar contractures, even in the extremities or the trunk. Subcutaneous pedicle flaps are effective for relatively wide contractures or quadratic contractures. When the skin tension across the contracture line is too great to use any local flap, such as a Z-plasty or V-Y plasty, the subcutaneous pedicle flap is particularly useful, because it can be freely designed in an area where the tension is small. When the flap contains some superficial scarring, the subcutaneous pedicle flap is preferred over other local flaps because of the superior vascularity and mobility.     

Neurovascular musculus obliquus internus abdominis flap free transfer for facial reanimation in a single stage

A study of the anatomy and transplantation of the musculus obliquus internus abdominis with a neurovascular pedicle transfer for facial reanimation in one stage is presented. Eleven adult cadavers (22 face sides) were dissected to observe the shape, thickness, innervation, and blood supply of the musculus obliquus internus abdominis. The blood supply of this muscle primarily comes from the musculus obliquus internus abdominis branch of the deep circumflex iliac artery (diameter, 1.3 +/- 0.2 mm), but it can also come from the eleventh intercostal artery (diameter, 1.14 +/- 0.3 mm) and the infracostal artery (diameter, 1.5 +/- 0.2 mm). The branch of the deep circumflex iliac artery and its vena comitans, or the infracostal artery and its vena comitans, could be anastomosed for muscle transplantation. The innervation of the musculus obliquus internus abdominis comes from the tenth and eleventh intercostal nerves (length, 12.7 +/- 1.5 cm) and the infracostal nerve (length, 12.9 +/- 1.3 cm). The eleventh intercostal nerve and the infracostal nerve were selected for anastomosis of muscle transplantation. From November of 1995 to November of 1999, 14 patients with long established facial paralysis were treated with transplantation of a musculus obliquus internus abdominis flap in one stage and were followed for 10 months to 6 years. In 13 patients, the dynamic functions of the transplanted muscles were restored, the obliqueness of the mouth and philtrum while static was corrected, and the facial muscle activities while smiling were harmonized. The eyelids of the paralyzed side could be closed postoperatively, indicating that the function of the orbicularis oculi of the paralyzed side was restored. The single-stage transplantation of a free musculus obliquus internus abdominis flap with one vascular, multi-nerve pedicle is a new method for facial reanimation in the treatment of long established facial paralysis. Because of the simplicity of the procedure and the completeness of the functional reanimation of the paralyzed facial muscles, compared with the results of other free muscle flap transfers, it is an ideal procedure for facial reanimation.     

The vascular anatomy and dissection of the free scapular flap

This article refers to the author's personal experience with a new scapular flap based on the dissection of 35 cadavers. In total, 70 free flaps were dissected. Its main advantages are the following: constancy of vascular anatomy; adequate size, length, and diameter of its vascular pedicle (which is formed by the cutaneous scapular artery and two veins); easy surgical dissection; primary closure of the donor site; and limited scar. However, this technique is not recommended in cases in which a large loss of substance is to be replaced. The first successful surgical application of the microsurgical scapular flap was performed in Paris in October of 1979.     

The medial adiposofascial flap of the leg: anatomical basis and clinical applications

Despite recent advances in microsurgical techniques, coverage of lower leg defects by locoregional flaps remains indicated in selected cases. The interest in these types of flaps has improved because recent clinical work advocates that fascial and fasciocutaneous flaps can be well indicated for bone coverage. The anatomical study of the medial adiposofascial flap is presented in this article. The flap is based on the rich vascular network supplied by the saphenous artery and the posterior tibial artery perforators. This flap can be harvested on the anteromedial aspect of the leg and can be mobilized to cover defects located between the patella and the heel. This multiple blood supply makes it possible to harvest this flap in various ways, so various defects can be covered. To confirm and prove the versatility and clinical value of this flap, the authors have studied a series of 22 cases in which this flap was used for coverage of lower leg defects. For these defects, especially when situated in the lower third or around the heel and ankle, coverage by a free flap is most often the only proposed solution. However, the authors have obtained excellent results in the majority of these cases, avoiding a free flap procedure. Moreover, in this way, the option of using a free flap remains possible if needed. There is minimal donor-site morbidity and a high functional and aesthetic outcome, making this flap a first-choice flap in selected cases of lower leg defects.     

The free thoracoumbilical flap for resurfacing large soft-tissue defects of the lower extremity

Both cadavers and living patients were studied regarding a method to resolve large skin defects with bone exposure in the leg, with long-distance thrombosis of the anterior tibial vessels or posterior tibial vessels resulting from traumatic lesions. Forty-six casting mold specimens of cadaveric legs were investigated. There were rich communication branches among the anterior tibial artery, posterior tibial artery, and fibular artery in the foot and ankle, which complemented each other well. Twenty-six patients with large skin defects with bone exposure in the proximal or middle segment of the leg were admitted to the authors' hospital. Among those patients, 19 demonstrated long-distance thrombosis of the anterior tibial vessels or posterior tibial vessels resulting from traumatic lesions. During treatment, a thoracoumbilical flap based on the inferior epigastric vessels was anastomosed to the distal stump of the anterior tibial vessels or the posterior tibial vessels, with reversed flow. All defects were successfully repaired, with good color and texture matches of the flaps. This method can be used for patients with normal anterior tibial vessels or posterior tibial vessels, normal distal stumps of the injured blood vessels, and good reversed flow. The method has the advantages of dissecting blood vessels in the recipient area during the débridement, not affecting the blood circulation of the injured leg, not sacrificing blood vessels of the opposite leg, and not fixing the patient in a forced posture. The muscles are less bulky in the distal one-third of the leg, and the blood vessels are shallow and can be dissected and anastomosed easily. When the flap is used for reconstruction in the proximal two-thirds of the leg, the blood vessel pedicle of the free flap is at a straight angle, without kinking.     

同种异体血管移植后肿瘤坏死因子表达的变化

目的探讨同种异体血管移植后移植血管和心肌肿瘤坏死因子(tumornecrosisfactor,TNF)表达的变化。方法取成年、雄性日本大白兔作为血管受者,新西兰大白兔为血管供者,进行颈动脉血管移植,通过免疫组织化学方法检测移植血管和心肌TNF表达的变化。结果自体原位移植组和液氮冷冻组TNF表达率低于新鲜移植组和抗生素处理组,新鲜移植组TNF表达率最高,与其它各组比较有显著性差异,P<0·05。血管移植后,心肌组织切片结果与血管移植组有类似结果:新鲜移植组心肌的TNF表达最高,与原位移植组和液氮冷冻组比较有显著性差异,P<0·05,而与抗生素处理组比较无显著差异性。结论液氮冷冻处理可降低移植血管和心肌TNF的产生;缺血再灌注损伤和/或免疫排斥反应能激发移植血管和全身各组织器官TNF的产生,从而造成移植血管的病理损害。     

Complications and vascular salvage of free-tissue transfers to the extremities

Complications were examined in 122 free flaps to lower and upper extremities in 104 patients, and vascular salvage was examined in 182 free flaps to lower and upper extremities in 158 patients. All patients were treated by the same surgeon. The overall survival rate of flaps was 96 percent. Complications occurred in 22 percent of the flaps. Complication rates were lower in patients with one free flap than in patients with two. Flaps had more vascular complications than nonvascular. Accompanying skin islands were found to be necessary to monitor vascularized bone transfers in order to avoid flap failure. Flow in the pedicle was reestablished in all flaps, but a higher percentage of flaps with longer ischemic times were lost. Although vascular compromise occurred frequently (15 percent), prompt surgical exploration and reexploration were thought to have greatly increased free-flap survival.     

Xenotransplantation of cryopreserved composite organs on the rabbit

Nowadays, It is easy to define optimal conditions (cryoprotective agent, speed and steps of freezing, speed of warming) for the cryopreservation of a homogeneous cell population or a one cell-layer tissue. Meanwhile, It is still hard to obtain cryopreservation of composite organs. Each tissue has its own requirements and its own reactivity to the cryopreservation process. The challenge consists of, on the one hand, to select the ideal combination of cryoprotective agents that can fit the needs of the different tissues, and the definition of adequate technical parameters, on the other hand. All the experimental trials have studied the survival rate of non-vascularized cryopreserved tissues. The aim of our experimental work is to demonstrate the feasibility of cryopreserving a composite organ with its nutrient vessels “artery and veins” in order after thawing to revitalize it by reestablishing the blood irrigation by microsurgical vascular anastomosis. We report our experimental results on the cryopreservation of composite organs - amputated digits - xenotransplanted in the rabbit. Digital segments were cryopreserved, then revitalized after warming using vascular microsurgical techniques. Preliminary results are encouraging and may pave the way in the future to the microvascular allotransplantation of cryopreserved composite organs.     

Xenotransplantation of cryopreserved composite organs on the rabbit

Nowadays, It is easy to define optimal conditions (cryoprotective agent, speed and steps of freezing, speed of warming) for the cryopreservation of a homogeneous cell population or a one cell-layer tissue. Meanwhile, It is still hard to obtain cryopreservation of composite organs. Each tissue has its own requirements and its own reactivity to the cryopreservation process. The challenge consists of, on the one hand, to select the ideal combination of cryoprotective agents that can fit the needs of the different tissues, and the definition of adequate technical parameters, on the other hand. All the experimental trials have studied the survival rate of non-vascularized cryopreserved tissues. The aim of our experimental work is to demonstrate the feasibility of cryopreserving a composite organ with its nutrient vessels “artery and veins” in order after thawing to revitalize it by reestablishing the blood irrigation by microsurgical vascular anastomosis. We report our experimental results on the cryopreservation of composite organs—amputated digits—xenotransplanted in the rabbit. Digital segments were cryopreserved, then revitalized after warming using vascular microsurgical techniques. Preliminary results are encouraging and may pave the way in the future to the microvascular allotransplantation of cryopreserved composite organs.