Sequential Free Flaps in Lower Extremity Reconstruction

Introduction

Sequential free flaps are often utilized for complex defects, particularly for recurrent head and neck tumors. However, their application in lower extremity (LE) reconstruction following trauma or oncology is less common. This study evaluated the indications, flap survival rates, and complications of sequential free flaps utilized in LE reconstruction.

Methods

Data from our multicenter database spanning from 2002 to 2020 were analyzed retrospectively through chart review. Adult patients who underwent sequential free flaps to the LE without complete initial flap loss were included. Outcome measures included ultimate flap viability and complications associated with sequential reconstructions.

Results

A total of 6 patients were identified: 2 patients (33%) required a second reconstruction following trauma, 1 patient (17%) following tumor recurrence, and 3 patients (50%) for chronic wounds related to infection. Most second free flaps survived (83%), with the exception of one in which the patient ultimately underwent a transfemoral amputation. Complications were observed in 3 patients (50%).

Conclusion

The main indication for second free flap reconstruction in the LE is the failure of durable wound closure with the first reconstruction, despite the absence of flap loss. In these complex scenarios, it is often prudent to utilize preoperative vascular imaging and to use distinct recipient vessels from those used in the first flap. Overall, sequential free flaps can be used in complex cases of limb salvage; however, they are associated with a substantial risk of complications.

Level of Evidence

Therapeutic-IV.

Ultrasound-guided preoperative skin-marking for deep inferior epigastric perforator flap surgery

Deep inferior epigastric artery perforator (DIEP) flaps remain the gold standard of autologous breast reconstruction. However, the surgical technique entails a steeper learning curve and typically requires a higher mean surgical time, in part due to the time and effort involved in physical localization of appropriate perforators at the time of surgery. This is typically performed using Doppler ultrasound, and is a potentially challenging and time-consuming task in the hands of an untrained operator. In order to mitigate these challenges, ease time pressures, promote efficient utilization of our operating theatres and improve surgical outcomes, our institution routinely performs skin-marking in advance at the Breast Radiology department. In this article, we describe our technique and experience with the procedure.

Morphology and arterial supply of the pyramidalis muscle in an Australian female population using computed tomography angiography

INTRODUCTION

The structure and function of the human anterolateral abdominal wall have been thoroughly described. However, there has been limited anatomical study of the pyramidalis muscle and its arterial supply. The aim of this study was to analyse the patterns of arterial supply to the pyramidalis in a female population.

METHODS

A retrospective study of 32 computed tomography angiography scans of the abdominal wall of adult women was performed to assess the prevalence (bilateral or unilateral presence, or absence), morphology (medial border height, base width and thickness) of pyramidalis and patterns of arterial supply.

RESULTS

Pyramidalis prevalence was bilateral in 75% of computed tomography angiography studies (24/32), unilateral in 6.3% (2/32) and absent in 18.8% (6/32). Of the five patterns of pyramidalis arterial supply observed and described in detail, the most frequent (68%, 34/50 of cases) originated from an exclusive muscular branch of the inferior epigastric artery. Origin from the pubic branch of the inferior epigastric artery was seen in 4% (2/50). There was a single case (2%, 1/50) of artery origin from a variant obturator artery, a common trunk with the pubic branch from the inferior epigastric artery, and from the muscular branch to rectus abdominis. The artery could not be defined in 22% (11/50).

CONCLUSION

In this computed tomography angiography study of women, five patterns of Pyramidalis arterial supply were identified. In the majority of cases, the pyramidalis derived its arterial supply from an exclusive, isolated muscular branch of the inferior epigastric artery.

Oncologic Staging Computed Tomography with IV Contrast Has Similar Efficacy to Dedicated Computed Tomography Angiography for Preoperative DIEP Flap Planning

Background

Due to variations in perforator vasculature, deep inferior epigastric artery perforator (DIEP) flap preoperative imaging can minimize operative time required to locate the most suitable perforators. Dedicated computed tomography angiography (CTA) has been the gold standard; however, many patients have already undergone a staging computed tomography (CT) per oncologic workup. The benefits from CTA may also be realized with a staging CT or CT with IV contrast.

Methods

Ten patients who underwent DIEP flap reconstruction with staging CT and CTA within 3 years of one another were included in this study. Reviewers evaluated axial views of both imaging modalities separately to identify each visible perforator in reference to the pubic symphysis from the xiphoid to the pubic symphysis. An intraclass correlation coefficient (ICC) was used to determine agreement in location of perforators between the two imaging studies. Statistical analysis was performed using an ICC and Wilcoxon signed rank-tests.

Results

The identified perforators within the patient cohort had an excellent correlation between their location on CT and CTA based upon ICC. The mean number of perforators identified in the CT group was 15.3 (SD 4.9) and in the CTA group was 18.8 (SD 6.4), which was not statistically different (P = 0.247).

Conclusions

CT has similar efficacy in identifying number of perforators and perforator location to dedicated CTA for preoperative planning in DIEP flaps. This has the potential for decreased patient contrast and ionizing radiation exposure as well as improved patient and healthcare resource utilization.

Multimodality Imaging of Postmastectomy Breast Reconstruction Techniques, Complications, and Tumor Recurrence

For women undergoing mastectomy, breast reconstruction can be performed by using implants or autologous tissue flaps. Mastectomy options include skin- and nipple-sparing techniques. Implant-based reconstruction can be performed with saline or silicone implants. Various autologous pedicled or free tissue flap reconstruction methods based on different tissue donor sites are available. The aesthetic outcomes of implant- and flap-based reconstructions can be improved with oncoplastic surgery, including autologous fat graft placement and nipple-areolar complex reconstruction. The authors provide an update on recent advances in implant reconstruction techniques and contemporary expanded options for autologous tissue flap reconstruction as it relates to imaging modalities. As breast cancer screening is not routinely performed in this clinical setting, tumor recurrence after mastectomy and reconstruction is often detected by palpation at physical examination. Most local recurrences occur within the skin and subcutaneous tissue. Diagnostic breast imaging continues to have a critical role in confirmation of disease recurrence. Knowledge of the spectrum of benign and abnormal imaging appearances in the reconstructed breast is important for postoperative evaluation of patients, including recognition of early and late postsurgical complications and breast cancer recurrence. The authors provide an overview of multimodality imaging of the postmastectomy reconstructed breast, as well as an update on screening guidelines and recommendations for this unique patient population. ©RSNA, 2024 Test Your Knowledge questions for this article are available in the supplemental material.

ACR Appropriateness Criteria® Imaging of Deep Inferior Epigastric Arteries for Surgical Planning (Breast Reconstruction Surgery): 2022 Update

Breast cancer is the most common malignancy in women in the United States, with surgical options including lumpectomy and mastectomy followed by breast reconstruction. Deep inferior epigastric perforator (DIEP) flap is a muscle-sparing perforator free flap breast reconstruction technique, which uses the deep inferior epigastric artery (DIEA) perforators to create a vascular pedicle. Multiple perforators are identified by preoperative imaging, which are typically ranked based on size, location, and intramuscular course. The goal of preoperative imaging is to aid the surgical team in preoperative planning given the variability of the DIEA perforator branches anatomy between patients. The objective of this document is to review the imaging modalities that can be used preoperatively to identify the optimal perforator and thereby reduce intraoperative complications, reduce postoperative complications, and improve clinical outcomes. The ACR Appropriateness Criteria are evidence-based guidelines for specific clinical conditions that are reviewed annually by a multidisciplinary expert panel. The guideline development and revision process support the systematic analysis of the medical literature from peer reviewed journals. Established methodology principles such as Grading of Recommendations Assessment, Development, and Evaluation or GRADE are adapted to evaluate the evidence. The RAND/UCLA Appropriateness Method User Manual provides the methodology to determine the appropriateness of imaging and treatment procedures for specific clinical scenarios. In those instances in which peer reviewed literature is lacking or equivocal, experts may be the primary evidentiary source available to formulate a recommendation.

Impact of Diameter of Perforator in Pedicle and Different Managements of Intermediate Non-Pedicle Perforator on Flap Survival in Rats

BACKGROUNDS

The quantified relationship between perforator diameter and flap length can be supported, and the impact of different strategies of managements of a non-pedicled perforator with two major subfascial divisions on flap survival has never been explored.

MATERIALS AND METHODS

This study was divided into two parts. In Part I, 48 Sprague-Dawley rats underwent flap harvesting based on six perforators with a diameter gradient. Then, the flap length and perforator diameter were measured for establishment of an equation. In Part II, 32 rats underwent harvest of a transverse flap based on the right superficial epigastric perforator. In 16 rats the right intermediate iliolumbar perforator was severed in a distal-to-division approach, whereas, in the other 16 rats, it was severed with in a proximal-to-division approach. Necrosis rates and blood perfusion were also compared.

RESULTS

The equation y = 13.02 × x + 2.29 could be established between the perforator diameter in the pedicle (x) and the flap length (y) that could be supported with R²=0.8963 and P < 0.001.The transverse flap with a distal-to-division management of the intermediate iliolumbar perforasome was weaker in perfusion and had a necrosis rate of 49±4%, whereas the flap with a proximal-to division management had a significantly stronger perfusion and a lower necrosis rate of 21±2% (P<0.001).

CONCLUSIONS

The safe flap length that can be estimated based on a perforator with a known diameter can be calculated using y=13.02× x +2.29. A short segment of the stem of an intermediate perforator with two major subfascial branches should be preserved to augment flap survival.

Successful endovascular embolization for traumatic subcutaneous abdominal wall hematoma via the superficial inferior epigastric artery: a case report

Abdominal wall hematoma (AWH) after blunt trauma is common, and most cases can be treated conservatively. More invasive treatment is required in patients with traumatic AWH if active bleeding is identified or there is no response to medical treatment. Herein, we report a case of endovascular embolization for traumatic subcutaneous AWH. Almost endovascular treatment for AWH is done through the deep inferior epigastric artery. However, in this case, the superficial inferior epigastric artery was the bleeding focus and embolization target. After understanding the vascular system of the abdominal wall, an endovascular approach and embolization is a safe and effective treatment option for AWH.

Improving the Safety of DIEP Flap Transplantation: Detailed Perforator Anatomy Study Using Preoperative CTA

Background: Deep inferior epigastric perforator and muscle sparing transverse rectus abdominis muscle flaps are commonly used flaps for autologous breast reconstruction. CT-angiography allows to analyse the perforator course preoperatively. Our aim was to compare the different aspects of perforator anatomy in the most detailed study. Methods: CT-angiographies of 300 female patients with autologous breast reconstruction of 10 years were analysed regarding the anatomy of the deep inferior epigastric artery and every perforator. Results: Overall, 2260 perforators were included. We identified correlations regarding the DIEA branching point and number of perforators and their intramuscular course. The largest perforator emerged more often from the medial branch of the DIEA than the smaller perforators (70% (416/595) vs. 54% (878/1634), p < 0.001) and more often had a direct connection to the SIEV (large 67% (401/595) vs. small 39% (634/1634), p < 0.01). Medial row perforators were larger than the laterals (lateral 1.44 mm ± 0.43 (n = 941) vs. medial 1.58 mm ± 0.52 (n = 1304) (p < 0.001)). The larger and more medial the perforator, the more likely it was connected to the SIEV: perforators with direct connection to the SIEV had a diameter of 1.65 mm ± 0.53 (n = 1050), perforators with indirect connection had a diameter of 1.43 ± 0.43 (n = 1028), perforators without connection had a diameter of 1.31 mm ± 0.37 (n = 169) (p < 0.001). Medial perforators were more often directly connected to the SIEV than lateral perforators (medial 56% (723/1302) vs. lateral 35% (327/941), p < 0.001). A lateral perforator more often had a short intramuscular course than medial perforators (69% (554/800) vs. 45% (474/1055), p < 0.001), which was also more often observed in the case of a small perforator and a caudal exit of the rectus sheath. Conclusion: The largest perforator emerges more often from the medial branch of the DIEA and frequently has a direct connection to the SIEV, making medial row perforators ideal for DIEP flap transplantation.

Current Applications of Ultrasound Imaging in the Preoperative Planning of DIEP Flaps

Background The deep inferior epigastric artery perforator (DIEP) flap has become the gold standard for autologous breast reconstruction at many institutions. Although the deep inferior epigastric artery displays significant anatomic variability in its intramuscular course, branching pattern and location of perforating vessels, the ability to preoperatively visualize and map relevant vascular anatomy has increased the efficiency, safety and reliability of the DIEP flap. While computed tomography angiography (CTA) is often cited as the preoperative imaging modality of choice for perforator flaps, more recent advances in ultrasound technology have made it an increasingly attractive alternative.

Methods An extensive literature review was performed to identify the most common applications of ultrasound technology in the preoperative planning of DIEP flaps.

Results This review demonstrated that multiple potential uses for ultrasound technology in DIEP flap reconstruction including preoperative perforator mapping, evaluation of the superficial inferior epigastric system and as a potential adjunct in flap delay procedures. Available studies suggest that ultrasound compares favorably to other widely-used imaging modalities for these indications.

Conclusion This article presents an in-depth review of the current applications of ultrasound in the preoperative planning of DIEP flaps and explores some potential areas for future investigation.

Septocutaneous gluteal artery perforator flap in breast reconstruction: An insight into the related anatomy and preoperative imaging

BACKGROUND

Although without a widespread popularity, the septocutaneous gluteal artery perforator flap (sc-GAP) can be an excellent choice in breast reconstruction. The purpose of the article is to further study the preoperative imaging anatomy and surgical technique for a safe operation.

PATIENTS AND METHODS

A clinical experience in four unilateral breast reconstructions is reported, and an analysis is made of the computed tomography angiography (CTA) variables (36 studies/72 sides) that might define the microsurgical consistency and reliability of the technique.

RESULTS

After a careful preoperative imaging evaluation, the surgical operation confirmed a predictable, although not straightforward, anatomy. All the flaps were raised in the supine position. With a remarkably quick postoperative recovery, the resulting scar was well hidden and did not significantly distort the gluteal aesthetics although contralateral contouring liposuction might be desirable in unilateral cases. Good aesthetic results were obtained in all the patients. In the evaluation of the CTA studies, a right/left septocutaneous perforator arising from the superficial branch of the superior gluteal artery could be found in 80.6% of the patients, with a few patients having 2-3 perforators on one side. Although with an overall suitable pedicle length (mean 7.4 cm), the arterial diameter at the suture site was found to be small (mean 1.6 mm).

CONCLUSION

Given the adequate body habitus and reconstructive requirements, the sc-GAP can be a good choice even in large breasts. However, the technique requires the appropriate surgical expertise and mandates a thorough preoperative imaging evaluation that defines whether the technique should be done in a particular patient.

Efficacy of perforator CTA of deep inferior epigastric artery perforator flap in preoperative planning of breast reconstruction: comparative study with CDUS

Background

The aim of the study is to compare the efficacy of perforator computed tomographic angiography (P-CTA) and color Doppler ultrasonography (CDUS) in preoperative planning of breast reconstruction with deep inferior epigastric artery perforator (DIEAP) flaps. From October 2018 to August 2019, 42 patients performed breast reconstruction with DIEAP flap procedures. All cases performed CDUS and multidetector perforator CT angiography (P-CTA) within 1 week prior to reconstructive surgery. The CDUS and P-CTA images were interpreted by two experienced vascular radiologists with 8- and 10-year experience, respectively, and compared with the surgical results.

Results

There were statistically significant differences (P = 0.0025) between CDUS and P-CTA in the detection of the number of perforators with P-CTA being more accurate than CDUS. There were significant differences between the P-CTA and surgical findings in measuring the caliber of dominant perforators (P = 0.002). CDUS was more accurate than P-CTA in this parameter showing sensitivity and specificity of 94 and 96%, respectively. There were significant differences between CDUS and surgical findings in the detection of the course of the intramuscular segment of the perforator (P = 0.0028). P-CTA was more accurate than CDUS in this parameter showing sensitivity and specificity of 96 and 97%, respectively.

Conclusion

The pre-operative mapping of perforators by CDUS and P-CTA proved to be effective and complementary to each other in the localization and vascular mapping of deep inferior epigastric artery perforators, thus greatly helping vascular surgeons in performing this surgical procedure.

Non-contrast-enhanced magnetic resonance angiography of facial arteries for pre-operative evaluation of vascularized submental lymph node flaps

Background

The aim of this study was to compare non-contrast-enhanced 3D phase contrast magnetic resonance angiography (3D PC-MRA) and conventional intravenous administration of contrast media, i.e., contrast-enhanced MRA (CE-MRA), to evaluate the courses of facial arteries for the preparation of vascularized submental lymph node flap (VSLN flap) transfer.

Methods

The head and neck regions of 20 patients with limb lymphedema were imaged using a 3 T MRI scanner. To improve the evaluation of facial artery courses, MRA was fused with anatomical structures generated by high-resolution T1-weighted imaging. The diagnostic and image qualities of facial arteries for VSLN flap planning were independently rated by two radiologists. Interobserver agreement was evaluated using Cohen’s kappa. Differences between 3D PC-MRA and CE-MRA in terms of the diagnostic quality of facial arteries were evaluated using McNemar’s test.

Results

Cohen’s kappa indicated fair to good interobserver agreement for the diagnostic and image qualities of the bilateral facial arteries. No significant difference in terms of the diagnostic quality of the left and right facial arteries between 3D PC-MRA and CE-MRA, respectively, was identified.

Conclusions

Non-contrast 3D PC-MRA is a reliable method for the evaluation of facial artery courses prior to VSLN flap transfer and could serve as an alternative to CE-MRA for patients with renal insufficiency or severe adverse reactions to contrast media.

The originating pattern of deep inferior epigastric artery: anatomical study and surgical considerations

PURPOSE

Studies focusing on the originating patterns of the deep inferior epigastric artery (DIEA) have not been conducted. Here, we analyzed the vascular anatomy of the DIEA with computed tomographic angiography (CTA) to provide assistance during proximal pedicle dissection of a DIEA-based flap.

METHODS

We conducted a retrospective study on patients who had undergone breast reconstruction with the transverse rectus abdominis musculocutaneous flap and the deep inferior epigastric perforator flap from March 2006 to October 2016. Preoperative three-dimensional computed tomographic angiograms of the abdominal wall (hemi-abdominal walls) were employed in this study, and three independent surgeons reviewed all CTA images. The originating angles and the distance from the originating point to the DIEA turning point were analyzed. Moreover, we assessed the relationship between the measured values and patients' characteristics, such as abdominal surgery history.

RESULTS

CTA data of 184 patients and 368 hemiabdomens were reviewed and analyzed. Most of the DIEAs originated from the external iliac artery in the medial direction, proceeded caudally, and curved in a cephalic direction. The average descending length was 11.29 mm. As the DIEA origin angle decreased (toward the caudal direction), the distance of the initial descent increased (r = 0.382, p < 0.01). In addition, the descending length was significantly larger (p < 0.01) in the operation group (12.22 mm) than in the non-operation group (9.86 mm).

CONCLUSIONS

Surgeons should consider DIEA-originating patterns to ensure safe pedicle dissection during flap elevation.

ACR Appropriateness Criteria® Imaging of Deep Inferior Epigastric Arteries for Surgical Planning (Breast Reconstruction Surgery)

Breast cancer is the most common malignancy in women in the United States. Breast reconstruction surgery is a commonly used therapy for patients with breast cancer. The technique for the deep inferior epigastric perforator flap uses a preserved rectus muscle, which decreases donor site morbidity. Accurate identification and measurement of the perforator branches of the deep inferior epigastric artery is pivotal during pre-operative planning so that the surgeon can prioritize the best vessel to use and ultimately improve clinical outcome. The American College of Radiology Appropriateness Criteria are evidence-based guidelines for specific clinical conditions that are reviewed annually by a multidisciplinary expert panel. The guideline development and revision include an extensive analysis of current medical literature from peer reviewed journals and the application of well-established methodologies (RAND/UCLA Appropriateness Method and Grading of Recommendations Assessment, Development, and Evaluation or GRADE) to rate the appropriateness of imaging and treatment procedures for specific clinical scenarios. In those instances where evidence is lacking or equivocal, expert opinion may supplement the available evidence to recommend imaging or treatment.

Living Donor Uterus Transplantation: A Single Center's Observations and Lessons Learned From Early Setbacks to Technical Success

Uterus transplantation is a vascularized composite allograft transplantation. It allows women who do not have a uterus to become pregnant and deliver a baby. In this paper, we analyze the first five cases of living donor uterus transplantation performed in the United States. The first three recipients lost their uterus grafts at days 14, 12, and 6, respectively, after transplant. Vascular complications, related to both inflow and outflow problems, were identified as the primary reason for the graft losses. Two recipients, at 6 and 3 mo, respectively, after transplant, have functioning grafts with regular menstrual cycles. Ultimate success will be claimed only after a live birth. This paper is an in-depth analysis of evaluation, surgical technique, and follow-up of these five living donor uterus transplants. The lessons learned were instrumental in allowing us to evolve from failure to technical and functional success. We aim to share our conclusions and build on knowledge in the evolving field of uterus transplantation.

Lengthening the pedicle of the rectus abdominis myocutaneous flap for repair of upper chest and neck defects

INTRODUCTION The aim of this study was to investigate whether the pedicle of the rectus abdominis flap can be lengthened by resecting the inferior costal cartilage segments or associated muscle when repairing upper body defects. A formula was generated that calculates the expected increase in pedicle length. METHODS Thirty patients underwent computed tomography. The width and thickness of the third to seventh inferior costal cartilage segments as well as the width of the respective intercostal spaces were recorded. Four patients underwent reconstruction of an upper body defect with the relevant flap. RESULTS The expected mean increases in pedicle length were 4.07cm (standard deviation [SD]: 0.31cm) and 4.63cm (SD: 0.54cm) following resection of the left and right sides respectively of the seventh inferior costal cartilage segment, 7.99cm (SD: 0.49cm) and 10.82cm (SD: 0.23cm) following resection of the left and right sides respectively of the sixth and seventh inferior costal cartilage segments while resection of the fourth to seventh inferior costal cartilage segments would equate to increases of 17.48cm (SD: 0.62cm) and 22.05cm (SD: 0.21cm) for the left and right sides respectively. In four patients who required reconstruction, three flaps survived without problems but one flap developed partial necrosis. CONCLUSIONS Resecting inferior costal cartilage segments or associated muscle can lengthen the pedicle of the rectus abdominis flap for reconstruction of defects on the upper chest and neck.

The Technique and Benefits of Angiographic Embolization of Inferior Epigastric Arteries Prior to Pedicled TRAM Flap Breast Reconstruction: Results from a Single Center

PURPOSE

To report a single center's experience with selective arterial embolization of the deep inferior epigastric arteries (DIEA) prior to pedicled TRAM flap breast reconstruction including techniques and outcomes.

MATERIALS AND METHODS

Retrospective chart review was performed for 15 patients who underwent pedicled TRAM flap breast reconstruction after selective embolization of bilateral DIEA. Data were analyzed to display the spectrum of postoperative outcomes following the TRAM flap procedure status post-selective angiographic embolization of the bilateral DIEA to improve vascularity of the TRAM flaps by rendering the tissue partially ischemic to undergo neovascularization. We then compared our results to historical controls of those delayed by ligating the DIEA via traditional surgical means to see if the outcomes are similar. We also compared our results to historical non-delayed TRAM flap reconstruction.

RESULTS

One patient had a small area of partial flap skin necrosis, and no patients had total flap loss. 13.3% of patients had clinically significant TRAM flap fat necrosis. Outcomes of TRAM flaps delayed by selective arterial embolization are comparable to historical controls of those delayed by traditional surgical means and better than non-delayed flaps.

CONCLUSION

Angiographic delayed TRAM flap reconstruction procedure is a reasonable safe alternative to the surgical delayed TRAM flap reconstruction procedure with less morbidity and is better than non-delayed TRAM flap procedures.

Location of the Deep Epigastric Vessels in the Resting and Insufflated Abdomen

STUDY OBJECTIVE

To determine whether the location of the superior and inferior epigastric vessels (deep epigastric vessels) change with abdominal insufflation.

DESIGN

Descriptive study (Canadian Task Force classification III).

SETTING

Tertiary care academic institution.

PATIENTS

Patients undergoing gynecologic laparoscopic surgery were recruited. A total of 35 subjects were enrolled.

INTERVENTIONS

Subjects underwent color Doppler ultrasound assessment of deep epigastric vessel location preoperatively and intraoperatively following abdominal insufflation. The deep epigastric vessels were identified at 5 points along the abdomen (pubic symphysis, anterior superior iliac spine [ASIS], umbilicus, xiphoid, and midpoint from umbilicus to xiphoid), with the distance from vessels to midline measured. Paired t tests and split-plot analysis of variance were used as appropriate.

MEASUREMENTS AND MAIN RESULTS

The mean patient age was 45.6 ± 16.5 years, and mean BMI was 29.8 ± 7.2. A significant difference between vessel location in the resting abdomen and insufflated abdomen was noted bilaterally at the ASIS, umbilicus, and midpoint from the umbilicus to the xiphoid. At each of these points, the deep epigastric vessels were found more laterally after insufflation on average, ranging from 0.6 ± 0.9 cm (p < .001) more laterally at the midpoint between the umbilicus and xiphoid to 1.1 ± 0.8 cm (p < .001) more laterally at the umbilicus. The most lateral location of the deep vessels after insufflation was seen at the ASIS (10.6 cm) and the umbilicus (10.9 cm). In a subanalysis of subjects grouped by body mass index (obese vs nonobese), deep epigastric vessels were more lateral in the insufflated abdomen of obese subjects compared with that of nonobese subjects at the ASIS, umbilicus, and midpoint from umbilicus to xiphoid (p < .05 for each point bilaterally).

CONCLUSION

The deep epigastric vessels shift laterally with abdominal insufflation, and may be found as far as 10.9 cm from the midline; this is more lateral than previously described and is clinically significant. Obesity is associated with a more lateral location of the deep epigastric vessels.

Localization of the dominant deep inferior epigastric artery perforator by computed tomography angiogram: does the standard deep inferior epigastric artery perforator flap design include the dominant perforator?

BACKGROUND

The deep inferior epigastric artery perforator (DIEP) free flap is the optimal autogenous reconstructive technique in many patients undergoing postmastectomy. Our aim was to evaluate the standard DIEP free flap design in relation to the dominant perforating vessels using computed tomography angiography (CTA).

METHODS

We retrospectively reviewed CTAs from 75 patients who had undergone perforator flap reconstruction within the past year. Locations of the largest perforator with a minimum diameter of 2.0 mm piercing the anterior rectus fascia were recorded.

RESULTS

Of 150 hemiabdomens reviewed, 146 (97.3%) had a dominant perforator. The median location for the dominant perforator was 3.3 cm lateral and 0.9 cm below the umbilicus. One hundred twenty-one (83%) of the dominant perforators arose within 3 cm of the umbilicus. One hundred one (69%) arose at or below the level of the umbilicus. Forty-five (31%) arose above the level of the umbilicus. Thirteen (9%) arose more than 2 cm above the umbilicus.

CONCLUSIONS

The standard DIEP flap design incorporates most of the dominant perforating vessels. However, a significant number of perforators arise at or above the umbilicus, which would be near the edge or out of the standard design of the DIEP. Our findings support the use of preoperative CTA in the evaluation of patients undergoing DIEP free flap reconstruction. Modification of flap design to include the dominant perforating vessels should be considered when the dominant vessel is outside the standard design of the DIEP.

Two-detector Computed Tomography Map of the Inferior Epigastric Vessels for Percutaneous Transabdominal Intervention Procedures

BACKGROUND

It is crucial to know anatomic variations and the exact course of an inferior epigastric artery (IEA) to prevent any complications during percutaneous abdominal interventions.

AIMS

The aim of this study was to map the inferior epigastric vessels using reconstructed two-detector computed tomography images and measure the distance from the inferior epigastric artery (IEA) to the midline to determine a safe route for percutaneous abdominal interventions.

STUDY DESIGN

Retrospective comparative study.

METHODS

Coronal reconstructed two-detector computed tomography images of 200 patients were evaluated to measure the distances between the IEA and midline at three levels (origin, middle, and distal). Vein and artery arrangements were documented.

RESULTS

The most frequently encountered arrangement (41.5%) was a single vein and artery on both sides. Mean distances on the right and left sides were 4.01 and 4.47 cm at the umbilical level, 3.81 and 4.26 cm at the midlevel, and 5.62 and 5.51 cm at the origin level. On both sides, measurement differences between the three levels were highly significant (p<0.05). In addition, a total of 56 IEA bifurcations were depicted in all 200 patients. Thirteen of the 56 bifurcations occurred only on the right side, 11 only on the left side, and 32 on both sides.

CONCLUSION

It is important to be attentive to the IEA's course, at different midline levels, when attempting percutaneous interventions via an abdominal approach.

Breast reconstruction with a deep inferior epigastric perforator flap: imaging appearances of the normal flap and common complications

OBJECTIVE

The purpose of this essay is to illustrate the normal imaging appearance of deep inferior epigastric perforator (DIEP) flap breast reconstruction and common postoperative complications.

CONCLUSION

Familiarity with the anatomy and normal imaging appearance of a DIEP flap reconstruction will help the breast imager recognize normal postsurgical findings and common postoperative complications.

Pre-operative CT angiography and three-dimensional image post processing for deep inferior epigastric perforator flap breast reconstructive surgery

Autologous breast reconstructive surgery with deep inferior epigastric artery (DIEA) perforator flaps has become the mainstay for breast reconstructive surgery. CT angiography and three-dimensional image post processing can depict the number, size, course and location of the DIEA perforating arteries for the pre-operative selection of the best artery to use for the tissue flap. Knowledge of the location and selection of the optimal perforating artery shortens operative times and decreases patient morbidity.