Breast reconstruction with the extended profunda artery perforator flap.

BACKGROUND: The profunda artery perforator (PAP) flap is a reliable flap for breast reconstruction. By extending the traditional flap, it is possible to include more tissue and thereby enhance flap volume. The aim of this study is to demonstrate the technique for extended profundal artery perforator flap harvest and to demonstrate results in a population otherwise not suited for autologous breast reconstruction. METHODS: Retrospective chart review of all patients who received extended PAP flap breast reconstruction between 2016 and 2018 was performed. Patient demographics, perioperative data, and postoperative complications were recorded in a pre-defined form and analyzed. A fully illustrated and step-by-step description of the procedure was created and included. RESULTS: A total of 46 extended PAP flaps for breast reconstruction were performed on 28 patients. Forty-three were 'regular' extended PAP flaps, one was a stacked flap, and two were transverse myocutaneous gracilis flaps with extended PAP flap skin design. Mean pre-operative breast volume was 330 cc, and mean flap weight was 400 g. The success rate was high (97.8%), and complications included one partial flap loss (2.2%), one wound dehiscence of the breast (2.2%), and wound dehiscence of the donor site (11 patients, 23.9%). CONCLUSIONS: The modified and extended profunda artery perforator flap is an excellent autologous tissue option for breast reconstruction even in large-breasted patients or patients with a relatively low body mass index. Advantages include higher flap volume, reliable blood supply, higher skin volume, and the possibility of choosing from several perforators, making dissection more convenient.

Alternative Perforator Options for Insufficient Profunda Artery Perforators: A Case and Anatomical Study.

INTRODUCTION: The profunda artery perforator (PAP) flap can be an alternative to the deep inferior epigastric artery flap. However, in some cases, the PAP may not be adequate to perfuse the whole flap. In this study, we describe 3 cases in which an alternative perforator was used for PAP flap perfusion. In addition, we describe an anatomical study to explore the perforasome of the PAP and alternative perforators. MATERIALS AND METHODS: Three cases are described in which an alternative perforator was used to successfully perfuse the pap flap. For the anatomical study, 7 PAP flaps were raised from cadavers. Ink was injected in the PAP, the gracilis perforator (GP) and the descending branch of the inferior gluteal artery perforator (DBIGA). Then, perfused area of the flap by each perforator was calculated. RESULTS: The 3 patients with alternative perforators recovered without complications, in addition, no signs of fat necrosis were observed. Concerning the anatomical study, mean perfusion area of the PAP pedicle was 204 ± 90 cm (range, 141-364 cm). The GP and the DBIGA had a perfusion area of 182 ± 42 cm (range, 123-235 cm) and 157 ± 22 cm (range, 136-192), respectively. CONCLUSION: Although the PAP flap has considerable benefits over the more traditional inferior gluteal artery perforator and transverse upper gracilis flaps, a plastic surgeon might encounter a PAP flap perforator that is not deemed viable for flap perfusion. In these cases, the GP and DBIGA may be suitable "escape" alternatives to complete the reconstruction.

Markers of blood coagulation and fibrinolysis in patients with early and delayed microsurgical reconstructions in the lower extremities.

BACKGROUND: In this study, markers of coagulation and fibrinolysis were assessed during early and delayed microsurgical reconstruction in patients with traumatic defects of their lower legs to analyse whether an imbalance of the hemostasis after trauma might predispose the development of vascular complications. METHODS: The prospective study included 70 patients. In 35 patients, surgery was performed within 72 hours after injury. In 35 other patients, delayed free flap transfer was performed between 14-21 days after trauma. In each group, reconstruction was performed with a fasciocutaneous anterior-lateral thigh flap (ALT, n = 18) or a myocutaneous flap (latissimus dorsi flap; n = 17). Blood samples were collected preoperatively, intraoperatively, and 3, 6, 12, 24, 36, 48, 72, 96 and 120 hours after the operation. Analysed parameters included markers of coagulation such as prothrombin fragment 1 + 2 (F1 + 2), thrombin-antithrombin III-complex (TAT), and antithrombin, as well as fibrinolysis markers such as plasminogenactivator inhibitor-I (PAI-1), tissue-plasminogenactivator (t-PA), and plasminogen. RESULTS: Preoperatively, levels of F1 + 2, TAT, and PAI-1 were significantly higher in patients with delayed reconstruction (p < .05). Patients with later vascular complications in this group (n = 5) presented a significant higher concentration of TAT, F1 + 2, and PAI-1 (p < .05). Twelve and 24 hours after free flap surgery, patients with vascular complications presented significant elevated levels of these markers (p < .05). CONCLUSIONS: Patients with delayed free flap surgery after lower leg trauma present a hypercoagulable state in their blood due to activation of the coagulation system and hypofibrinolysis. Early reconstruction might minimise the risk of flap failure caused by hypercoagulability.

Medial lower leg perforators: An anatomical study of their distribution and characteristics.

PURPOSE: The integument of the medial lower leg is underestimated as a donor site for local and distant reconstructions. Comprehensive knowledge of its perforator anatomy is lacking. This study aims to determine perforator location and characteristics and to compare these regarding the proximal, middle and distal third of the medial lower leg. MATERIALS AND METHODS: The medial lower leg region (MLLR) of 16 cadavers was delineated and investigated after injecting the popliteal artery with acrylic paint. Following dissection, all perforators larger than 0.3 mm were localized and mapped. Their course, source vessel, length and diameter were subsequently documented. RESULTS: Overall, 122 perforators were found, 102 (83.6%) originating from the posterior tibial artery, 16 (13.1%) from the medial sural artery and 4 (3.3%) from the anterior tibial artery. A mean of 7.6 ± 2.4 perforators (range 4-13) per MLLR was found. Most perforators (42.6%) were localized in the distal third of the MLLR, followed by the middle (36.9%) and proximal third (20.5%). The largest and longest perforators were found in the proximal third of the MLLR (diameter 1.4 mm, length 9.1 cm), followed by the middle and distal third respectively. Of all musculocutaneous perforators, the majority (78.6%) was located in the middle third of the MLLR. Of all septocutaneous perforators, most (55.3%) were found in the distal third of the MLLR. A small number of unexpected anatomical variants were found. CONCLUSION: In each third of the MLLR different perforator characteristics were found. Knowledge of these characteristics can be used to direct the reconstructive plan. © 2016 Wiley Periodicals, Inc. Microsurgery 37:319-326, 2017.

The proximally based long peroneal muscle turnover flap: A novel salvage flap for small to medium-sized defects of the knee.

BACKGROUND AND AIM: Coverage of soft-tissue defects of the knee due to multiple operations, trauma, and infection remains a surgical challenge. Often, these defects are repaired using free tissue transfer. The aim of this study was to find an easy and reliable local method of repair for small to medium-sized defects. The authors describe a new surgical option for tissue coverage using a proximally based long peroneal muscle turnover flap (LPTF) with split-thickness skin graft. METHODS: Proximally based LPTFs were harvested and transposed into same-size created defects in five cadavers. After optimizing this technique, it was clinically used in two patients with defects secondary to total knee replacement revisions. RESULTS: Average cadaver flap size was 4.7 × 15.8 cm allowing reach of all knee joint areas and was based consistently on a sufficient (2-mm-diameter average) proximal arterial branch of the anterior tibial artery. Donor sites were closed without tension. Subsequent application of the flap on two patients resulted in good functional outcome. CONCLUSION: The proximally based LPTF is a new option available in the reconstruction of knee defects and should be added to the reconstructive surgeon's armamentarium of pedicled flaps, providing short operating time and promising clinical outcome.

Breast Reconstruction Using the Geometrically Modified Profunda Artery Perforator Flap From the Posteromedial Thigh Region: Combining the Benefits of Its Predecessors.

BACKGROUND: Occasionally, the deep inferior epigastric perforator flap is unavailable for autologous breast reconstruction. Alternative options, such as gluteal artery perforator flaps, the transverse upper gracilis flap, and the profunda artery perforator (PAP) flap, have been well documented. In our initial experience, the PAP flap was associated with limitations at the donor site. Therefore, a geometrically modified PAP flap was evaluated. METHODS: Forty geometrically modified PAP flap reconstructions were performed on 30 patients. Our modification comprised flap harvest from a more cranial area, hereby adding abundant inferior gluteal tissue to the flap while sparing superior thigh tissue. Patient characteristics, anatomical variables, and clinical outcome were prospectively evaluated. RESULTS: Mean patient age was 44 years, and mean body mass index (BMI) was 23.3 kg/m. Mean flap size was 32 × 12 cm, and mean weight was 385 g. Mean number of suitable perforators (diameter ≥ 0.5 mm) in the adductor magnus area was 1.7 per thigh. All flaps survived completely. Wound dehiscence at the donor site occurred after 4 unilateral reconstructions. Transient lymphedema of the leg occurred after 4 other unilateral reconstructions. Other wound morbidity or systemic complications did not occur. Secondary breast surgery for symmetry and volume was indicated after 16 reconstructions. Preoperative bra size was unchanged or larger in 36 reconstructions. Scar position in the crease was achieved after 39 reconstructions. Sensibility changes of the posteromedial thigh region were not observed. CONCLUSIONS: The geometrically modified PAP flap ensures in-the-crease scar positioning and provides sufficient tissue to restore preoperative bra size.

Lateral lower leg perforator flaps: an anatomical study to localize and classify lateral lower leg perforators.

Despite increasing use of lateral lower leg perforator flaps, comprehensive anatomical data are still lacking. The aim of this article was to comprehensively document the pattern of usable lateral lower leg perforators. Systematic mapping of 16 cadaver leg perforators in a well-defined area was performed to elucidate location, course, length, diameter, and origin. Overall, 197 perforators were found in 16 lateral lower legs. The mean number of perforators per leg with a diameter ≥ 0.3 mm was 13.4 ± 3.6. Most perforators were found in the distal third (39.0%), followed by the middle third (32.0%), and proximal third (29.0%). A musculocutaneous course was found in 26.9% of the perforators, whereas 73.1% revealed a septocutaneous course. Most septocutaneous perforators (50.0%) were found in the distal third and most musculocutaneous perforators (58.5%) in the proximal third (P < 0.001). The majority of perforators originated from the anterior tibial artery (53.0%), followed by the peroneal artery (41.6%), and the popliteal artery (5.1%). Popliteal artery perforators (1.64 mm) were significantly larger than anterior tibial artery (0.91 mm) and peroneal artery perforators (1.02 mm; P < 0.001). These results may facilitate tissue transfer around the lateral lower leg.

Posterior thigh perforator flaps: an anatomical study to localize and classify posterior thigh perforators.

In the last decade perforator flaps have been used increasingly for different indications. Many regions may serve as donor site. In this respect the posterior thigh region (PTR) has been neglected as a potential donor site for many years. The purpose of this study was to provide complete mapping of perforators supplying the posterior thigh region. Twelve fresh cadaver thighs were prepared injecting diluted acrylic paint into the iliac artery. Thereafter the posterior thighs were dissected from medial to lateral, distinguishing the perforators at the level of the superficial fascia. The perforators were localized and origin, source, length and diameter of the perforators were documented. Analysis occurred using ANOVA and the two proportion Z test. The distribution of musculocutaneous and septocutaneous perforators was respectively 69.1% and 30.9% (P = 0.002). The PTR was divided in thirds. Most perforators (53.2%) were found in de middle third of the PTR. The deep femoral artery (DFA) was the main origin of perforators (61.7%), followed by the superficial femoral artery (SFA) (27.7%) and the popliteal artery (PA) (10.6%). The DFA perforators were the longest with a mean length of 13.7 ± 4,69 cm, the SFA perforators were 9.79 ± 3.76 cm and the PA perforators were 8.6 ± 3.37 cm. The PTR offers a sufficient number of suitable perforators to serve as an adequate donorsite for pedicled and free flaps.

Humanized mouse model of skin inflammation is characterized by disturbed keratinocyte differentiation and influx of IL-17A producing T cells.

Humanized mouse models offer a challenging possibility to study human cell function in vivo. In the huPBL-SCID-huSkin allograft model human skin is transplanted onto immunodeficient mice and allowed to heal. Thereafter allogeneic human peripheral blood mononuclear cells are infused intra peritoneally to induce T cell mediated inflammation and microvessel destruction of the human skin. This model has great potential for in vivo study of human immune cells in (skin) inflammatory processes and for preclinical screening of systemically administered immunomodulating agents. Here we studied the inflammatory skin response of human keratinocytes and human T cells and the concomitant systemic human T cell response.As new findings in the inflamed human skin of the huPBL-SCID-huSkin model we here identified: 1. Parameters of dermal pathology that enable precise quantification of the local skin inflammatory response exemplified by acanthosis, increased expression of human ß-defensin-2, Elafin, K16, Ki67 and reduced expression of K10 by microscopy and immunohistochemistry. 2. Induction of human cytokines and chemokines using quantitative real-time PCR. 3. Influx of inflammation associated IL-17A-producing human CD4+ and CD8+ T cells as well as immunoregulatory CD4+Foxp3+ cells using immunohistochemistry and -fluorescence, suggesting that active immune regulation is taking place locally in the inflamed skin. 4. Systemic responses that revealed activated and proliferating human CD4+ and CD8+ T cells that acquired homing marker expression of CD62L and CLA. Finally, we demonstrated the value of the newly identified parameters by showing significant changes upon systemic treatment with the T cell inhibitory agents cyclosporine-A and rapamycin. In summary, here we equipped the huPBL-SCID-huSkin humanized mouse model with relevant tools not only to quantify the inflammatory dermal response, but also to monitor the peripheral immune status. This combined approach will gain our understanding of the dermal immunopathology in humans and benefit the development of novel therapeutics for controlling inflammatory skin diseases.

Anteromedial thigh flaps: an anatomical study to localize and classify anteromedial thigh perforators.

Until now, research on flaps in the anteromedial thigh region has focused on flaps in specific regions. To elucidate the complete pattern of suitable anteromedial thigh perforators, an anatomical study was performed by dissecting nine thighs from different cadavers. The ideal perforator has maximum length and diameter and runs through a septum. According to the data found in our study, these perforators can predominantly be found in the middle third of the anteromedial thigh region. All of the three main thigh vessels supply perforators which can be used for flaps. Pertaining to length and diameter the most suitable perforators originate from the deep femoral artery, which can be found in the proximal and middle third of the anteromedial thigh. Musculocutaneous perforators are found to be longer than septocutaneous perforators. Because of their position, the proximal and distal third perforators should preferentially be used for local pedicled flaps. Defects in the pelvic area and around the knee can be closed with perforator flaps from the proximal and distal anteromedial thigh, respectively. Because of their diameter, length, and number, the middle third perforators should be the first choice for harvesting free flaps. Skin closure is easily achieved in the anteromedial thigh region even when larger flaps are used.