Development of a porcine training model for microvascular fasciocutaneous free flap reconstruction.

BACKGROUND: In reconstructive surgery, improvements are needed in the effective teaching of free flap surgery. There is a need for easily accessible and widely available training without high financial costs or ethical concerns while still providing a realistic experience. Our aim was to develop an appropriate training model for microvascular flaps. METHODS: We identified pig head halves as most appropriate regarding availability, cost, and realism. These accrue largely by the food industry, so no animals need to be sacrificed, making it more ethical from an animal welfare perspective. We evaluated the suitability as flap donor site and analyzed the vascular anatomy of 51 specimens. RESULTS: Anatomical evaluation revealed a reliable and constant vascular anatomy, allowing the design of a flap model that can effectively illustrate the entire process of microvascular flap surgery. The process was divided into 6 key steps. The flap can be harvested after marking the vascular pedicle 5.3 cm from the lateral corner of the mouth. Skin island design and subsequent tissue dissection follow until a fasciocutaneous flap is raised, similar to a radial flap. Upon completion of flap harvesting, it can be freely transferred for defect reconstruction. Microvascular anastomosis can be performed on recipient vessels in the cervical region, and the difficulty can be individually adjusted. CONCLUSIONS: The developed training model is a reasonable compromise in terms of surgical realism, availability, didactic value, and cost/time effectiveness. We believe it is a powerful and effective tool with high potential for improving surgical education and training.

Assessment of changes in vessel area during needle manipulation in microvascular anastomosis using a deep learning-based semantic segmentation algorithm: A pilot study.

Appropriate needle manipulation to avoid abrupt deformation of fragile vessels is a critical determinant of the success of microvascular anastomosis. However, no study has yet evaluated the area changes in surgical objects using surgical videos. The present study therefore aimed to develop a deep learning-based semantic segmentation algorithm to assess the area change of vessels during microvascular anastomosis for objective surgical skill assessment with regard to the "respect for tissue." The semantic segmentation algorithm was trained based on a ResNet-50 network using microvascular end-to-side anastomosis training videos with artificial blood vessels. Using the created model, video parameters during a single stitch completion task, including the coefficient of variation of vessel area (CV-VA), relative change in vessel area per unit time (ΔVA), and the number of tissue deformation errors (TDE), as defined by a ΔVA threshold, were compared between expert and novice surgeons. A high validation accuracy (99.1%) and Intersection over Union (0.93) were obtained for the auto-segmentation model. During the single-stitch task, the expert surgeons displayed lower values of CV-VA (p < 0.05) and ΔVA (p < 0.05). Additionally, experts committed significantly fewer TDEs than novices (p < 0.05), and completed the task in a shorter time (p < 0.01). Receiver operating curve analyses indicated relatively strong discriminative capabilities for each video parameter and task completion time, while the combined use of the task completion time and video parameters demonstrated complete discriminative power between experts and novices. In conclusion, the assessment of changes in the vessel area during microvascular anastomosis using a deep learning-based semantic segmentation algorithm is presented as a novel concept for evaluating microsurgical performance. This will be useful in future computer-aided devices to enhance surgical education and patient safety.

[Online training for hearing implant surgery : A new approach to otological training. German version]. / Online-Training für Hörimplantatchirurgie : Ein neuer Ansatz in der otologischen Ausbildung.

OBJECTIVE: Education in microsurgery of the ear includes staged training to allow for mastering of the complex microsurgical procedures, particularly in the context of middle ear reconstruction and cochlear implantation. Traditional surgical training includes temporal bone preparations by cadaver dissection and supervised operating room practice. As these on-site trainings are limited, there is a need to broaden education facilities in an on-line format. Therefore, a first basic on-line training for otosurgery was developed. MATERIALS AND METHODS: The system consists of an artificial temporal bone model together with a set of basic surgical instruments and implant dummies. As an essential part of the training kit, a high-resolution camera set is included that allows for connection to a video streaming platform and enables remote supervision of the trainees' surgical steps by experienced otological surgeons. In addition, a pre-learning platform covering temporal bone anatomy and instrumentation and pre-recorded lectures and instructional videos has been developed to allow trainees to review and reinforce their understanding before hands-on practice. RESULTS: Over the three courses held to date, 28 participants with varying levels of prior surgical experience took part in this otological surgical training program. The immediate feedback of the participants was evaluated by means of a questionnaire. On this basis, the high value of the program became apparent and specific areas could by identified where further refinements could lead to an even more robust training experience. CONCLUSION: The presented program of an otosurgical online training allows for basal education in practical exercises on a remote system. In this way, trainees who have no direct access to on-site instruction facilities in ear surgery now have the chance to start their otosurgical training in an educational setting adapted to modern technologies.

The Sellar Region as Seen from Transcranial and Endonasal Perspectives: Exploring Bony Landmarks Through New Surface Photorealistic Three-Dimensional Model Reconstruction for Neurosurgical Anatomy Training.

BACKGROUND: Virtual reality-based learning of neuroanatomy is a new feasible method to explore, visualize, and dissect interactively complex anatomic regions. We provide a new interactive photorealistic three-dimensional (3D) model of sellar region microsurgical anatomy that allows side-by-side views of exocranial and endocranial surfaces to be explored, with the aim of assisting young neurosurgery residents in learning microsurgical anatomy of this complex region. METHODS: Four head specimens underwent an endoscopic endonasal approach extended to the anterior and posterior skull base to expose the main bony anatomic landmarks of the sellar region. The same bony structures were exposed from a transcranial perspective. By using a photogrammetry method, multiple photographs from both endocranial and exocranial perspectives, different for angulations and depth, were captured, fused, and processed through dedicated software. RESULTS: All relevant bony structures were clearly distinguishable in the 3D model reconstruction, which provides several benefits in neuroanatomy learning: first, it replicates bony structures with high degrees of realism, accuracy, and fidelity; in addition, it provides realistic spatial perception of the depth of the visualized structures and their anatomic relationships; again, the 3D model is interactive and allows a 360° self-guided tour of the reconstructed object, so that the learner can read the bones and their anatomic relationship from all desired points of view. CONCLUSIONS: Detailed knowledge of key surgical landmarks representing keyholes and/or anatomic structures to not violate is mandatory for safer surgery, especially for a complex region such as the skull base. Highly accurate virtual and functional neurosurgical models, such as photogrammetry, can generate a realistic appearance to further improve surgical simulators and learn neuroanatomy.

Assessment of Microsurgery Simulation Course Access in Plastic Surgery Training Programs.

BACKGROUND: Microsurgery requires complex skill development with a steep learning curve for plastic surgery trainees. Flap dissection courses and simulation exercises are useful to acquire these skills. This study aims to assess plastic surgery training programs' access to and interest in microsurgical courses. METHODS: A survey was distributed to plastic surgery residency and microsurgery fellowship program directors (PDs). The survey collected program demographics and attendance of trainees at structured microsurgical skills or flap dissection courses. We assessed if PDs thought trainees would benefit from instructional courses. RESULTS: There were 44 residency PD responses (44/105, 41.9%, 36 integrated, 8 independent), and 16 fellowship PD responses (16/42, 38.1%). For residency PDs, 54.5% (24/44) sent residents to flap courses, and 95% (19/20) of remaining PDs felt residents would benefit from attending. In addition, 59.1% of programs (26/44) sent residents to microsurgical skills courses, and 83.3% (15/18) of remaining PDs felt residents would benefit from attending. When examining fellowship PDs, 31.2% of programs (5/16) sent fellows to flap dissection courses and 10/11 of remaining PDs felt fellows would benefit from attending a course (90.1%). Half of programs (8/16) sent fellows to microsurgical skills courses, and 7/8 remaining PDs felt fellows would benefit from attending (87.5%). CONCLUSION: Only half of the plastic surgery trainees have access to microsurgical skills and flap dissection courses. The majority of residency and fellowship PDs feel that training courses are valuable. Expanding access to these courses could provide a significant benefit to microsurgical education in plastic surgery training.

Beyond Borders: A Global Microsurgery Training and Case Exposure Survey.

BACKGROUND: Microsurgery is essential in modern reconstructive surgery and plastic surgery training. Surgeon's proficiency and experience are crucial for effective microsurgical interventions. Despite anecdotal evidence of varying quality of microsurgery training globally, no empirical studies have investigated this. We conducted a global survey to investigate microsurgical training and clinical case exposure among plastic surgery trainees worldwide. METHODS: An online survey was conducted using a secure platform to gather information on microsurgical case exposure and training among plastic surgery trainees between August 2020 and April 2021. Participants provided consent and completed a 37-question survey across four themes: clinical caseload, surgical exposure to microsurgery, microsurgical simulation training exposure, and barriers and opportunities. RESULTS: A total of 202 responses were received, with most respondents in formal training programs (86.7%). The data highlighted regional variation in microsurgery case indications and flap types, with North America and Europe exhibiting the highest activity levels in microsurgery. Trainees in Asia have the highest cumulative practical exposure in microsurgery, followed by Australia and Oceania, and North America. Only 39.6% of respondents reported formal microsurgical simulation training, and almost one-third (29.7%) received no simulation training. Trainee access to practical experience is limited by several factors, including insufficient time and procedure complexity. Notably, practical experience was most commonly denied without reason being given. CONCLUSION: Our study highlights significant disparities in microsurgical training and exposure among plastic surgery trainees globally. Further research is needed to identify strategies for addressing these issues, given the growing demand for complex reconstructive microsurgery and its impact on health care inequalities.

Latex-Infused Porcine Abdominal Model: A Novel Microsurgery Simulator for Deep Inferior Epigastric Perforator Dissection.

BACKGROUND: Perforator dissection and flap elevation are routinely performed for microsurgical reconstruction; however, there is a steep learning curve to mastering these technical skills. Though live porcine models have been utilized as a microsurgical training model, there are significant drawbacks that limit their use, including cost, limited ability for repetition, and obstacles associated with animal care. Here we describe the creation of a novel perforator dissection model using latex augmented non-living porcine abdominal walls. We provide anatomic measurements that demonstrate valuable similarities and differences to human anatomy to maximize microsurgical trainee practice. METHODS: Six latex-infused porcine abdomens were dissected based on the deep cranial epigastric artery (DCEA). Dissection was centered over the abdominal wall mid-segment between the second and fourth nipple line. Dissection steps included exposure of lateral and medial row perforators, incision of anterior rectus sheath with perforator dissection, and dissection of DCEA pedicle. DCEA pedicle and perforator measurements were compared with deep inferior epigastric artery (DIEA) data in the literature. RESULTS: An average of seven perforators were consistently identified within each flap. Assembly of the model was performed quickly and allowed for two training sessions per specimen. Porcine abdominal walls demonstrate similar DCEA pedicle (2.6 ± 0.21 mm) and perforator (1.0 ± 0.18 mm) size compared with a human's DIEA (2.7 ± 0.27 mm, 1.1 ± 0.85 mm). CONCLUSION: The latex-infused porcine abdominal model is a novel, realistic simulation for perforator dissection practice for microsurgical trainees. Impact on resident comfort and confidence within a microsurgical training course is forthcoming.

Low-fidelity simulation models in urology resident's microsurgery training.

PURPOSE: To evaluate the gain of microsurgical skills and competencies by urology residents, using low-fidelity experimental models. METHODS: The study involved the use of training boards, together with a low-fidelity microsurgery simulator, developed using a 3D printer. The model consists in two silicone tubes, coated with a resin, measuring 10 cm in length and with internal and external diameters of 0.5 and 1.5 mm. The support for the ducts is composed by a small box, developed with polylactic acid. The evaluation of the gain of skills and competencies in microsurgery occurred throughout a training course consisting of five training sessions. The first sessions (S1-S4) took place at weekly intervals and the last session (S5) was performed three months after S4. During sessions, were analyzed: the speed of performing microsurgical sutures in the pre and post-training and the performance of each resident through the Objective Structure Assessment of Technical Skill (OSATS) and Student Satisfaction Self-Confidence tools in Learning (SSSCL). RESULTS: There was a decrease in the time needed to perform the anastomosis (p=0.0019), as well as a progressive increase in the score in the OSATS over during sessions S1 to S4. At S5, there was a slightly decrease in performance (p<0.0001), however, remaining within the expected plateau for the gain of skills and competences. The SSSCL satisfaction scale showed an overall approval rating of 96.9%, with a Cronback alpha coefficient of 83%. CONCLUSIONS: The low-fidelity simulation was able to guarantee urology residents a solid gain in skills and competencies in microsurgery.

A Deep Learning Approach to Classify Surgical Skill in Microsurgery Using Force Data from a Novel Sensorised Surgical Glove.

Microsurgery serves as the foundation for numerous operative procedures. Given its highly technical nature, the assessment of surgical skill becomes an essential component of clinical practice and microsurgery education. The interaction forces between surgical tools and tissues play a pivotal role in surgical success, making them a valuable indicator of surgical skill. In this study, we employ six distinct deep learning architectures (LSTM, GRU, Bi-LSTM, CLDNN, TCN, Transformer) specifically designed for the classification of surgical skill levels. We use force data obtained from a novel sensorized surgical glove utilized during a microsurgical task. To enhance the performance of our models, we propose six data augmentation techniques. The proposed frameworks are accompanied by a comprehensive analysis, both quantitative and qualitative, including experiments conducted with two cross-validation schemes and interpretable visualizations of the network's decision-making process. Our experimental results show that CLDNN and TCN are the top-performing models, achieving impressive accuracy rates of 96.16% and 97.45%, respectively. This not only underscores the effectiveness of our proposed architectures, but also serves as compelling evidence that the force data obtained through the sensorized surgical glove contains valuable information regarding surgical skill.

Microsurgery Robots: Applications, Design, and Development.

Microsurgical techniques have been widely utilized in various surgical specialties, such as ophthalmology, neurosurgery, and otolaryngology, which require intricate and precise surgical tool manipulation on a small scale. In microsurgery, operations on delicate vessels or tissues require high standards in surgeons' skills. This exceptionally high requirement in skills leads to a steep learning curve and lengthy training before the surgeons can perform microsurgical procedures with quality outcomes. The microsurgery robot (MSR), which can improve surgeons' operation skills through various functions, has received extensive research attention in the past three decades. There have been many review papers summarizing the research on MSR for specific surgical specialties. However, an in-depth review of the relevant technologies used in MSR systems is limited in the literature. This review details the technical challenges in microsurgery, and systematically summarizes the key technologies in MSR with a developmental perspective from the basic structural mechanism design, to the perception and human-machine interaction methods, and further to the ability in achieving a certain level of autonomy. By presenting and comparing the methods and technologies in this cutting-edge research, this paper aims to provide readers with a comprehensive understanding of the current state of MSR research and identify potential directions for future development in MSR.

Novices can assess microsurgery performance, and this is enhanced using the Manual Suture Parameters for Training and Assessment (M-SParTA) scoring system.

This study explores how novices could effectively evaluate the quality of microsurgical suturing. That would be enhanced with using a novel Manual Suture Parameters for Training and Assessment (M-SParTA), which supported novices with guidance on the objective parameters, in order to increased the accuracy of scoring ability. We also propose the following initial framework to train novices in microsuturing using a standardised task: 1) Exposure; 2) Assessment; 3) Hands-on and self-assessment. The independent learning cycle with targeted supervision provides novices with greater autonomy and a less stressful environment that could enhance skills training.

Training in microvascular anastomosis - A randomized comparative study between chicken thigh specimen and live rat.

Training in microsurgical techniques on live rats is the gold standard, but raises ethical issues related to animal welfare and cost. The aim of this study was to compare acquisition of microsurgical techniques with primary training on chicken thigh specimens. Seventy six students were randomly assigned: 23 to exclusive rat training and 53 to primary chicken-leg training. Both groups were then evaluated on aortic suture and jugular aortic bypass surgery in live rats. The primary criterion for successful anastomosis was the patency test. The survival of the rat, the number of severe vascular wounds and the quality of the dissection were also assessed. Aortic anastomoses were of significantly better quality in the chicken group (p = 0.041). There was no significant difference in the number of serious injuries, rat mortality, or quality of dissection (p > 0.05). For jugular aortic bypass surgery, dissection quality (p = 0.02) and patency test (p = 0.05) were better in the chicken-leg group. There was no significant difference in number of severe wounds or rat mortality (p > 0.05). Students who started their microsurgical training on a chicken leg did not perform worse than those with exclusive live rat training. Initial training on chicken thigh specimens seems to be a reliable alternative to training on live models. LEVEL OF EVIDENCE: Level II - Randomized controlled trial.

Course Review: Yorkshire Microsurgery Course 2023.

ABSTRACT: Microsurgery is an advanced set of techniques that require a high level of skill to be performed safely. Surgical skills courses offer safe environments for practice in such skills and form a fundamental part of surgical training. The Yorkshire Microsurgery Course is a 3-day course at Bradford Royal Infirmary, United Kingdom. Delivered via short lectures followed by supervised practical sessions, the course aims to provide delegates with the essential knowledge and skills required for microsurgery.We detail an outline and critical evaluation of the February 2023 iteration of the course, with recommendations for improvement.Overall, we found the course excellent. It provided delegates with a solid grounding in the fundamentals of microsurgery and the opportunity for personalized practice supervised by experts. We would recommend this course to colleagues interested in a career in plastic surgery.

Evaluation of konjac noodle as a microsurgery training model: learning curve analysis.

BACKGROUND: classical models of microsurgical anastomosis training are expensive and have ethical implications. Some alternatives join low cost and easiness to store. However, the translation of knowledge acquired by training in these methods into the traditional ones is not clear. This project aims to assess the feasibility of konjac noodles as a reliable microsurgery-training model. METHODS: 10 neurosurgery residents performed an end-to-end anastomosis in a 2-3mm placenta artery. The anastomoses were evaluated quantitatively, recording time; and qualitatively, applying a validated score (Anastomosis Lapse Index - ALI) by three experienced neurosurgeons and verifying the presence of gross leakage through the infusion of fluorescein. Subsequently, they performed 10 non-consecutive sessions of anastomosis training in the konjac noodle. Eventually, a final anastomosis in the placenta model was performed and the same parameters were scored. RESULTS: we observed a 17min reduction in the mean time to perform the anastomosis in the placenta model after the training in the konjac (p<0.05). There was a non-significant 20% reduction in gross leakage, but the training sessions were not able to consistently improve the ALI score. CONCLUSIONS: we demonstrate a reduction in anastomosis performing time in placental arteries after training sessions in the konjac noodle model, which can be regarded as a feasible low-cost method, particularly useful in centers with surgical microscopes only in the operation room.

Validation of a simplified evaluation grid applied to the microsurgery on inert material via smartphone.

OBJECTIVES: Microsurgery is usually performed in experimental research models and clinical surgery. It requires meticulous technical skills and continuous training. Inert materials such as Shirataki noodles are readily available and low-cost consumables regularly used for practice. The objective of this study was to evaluate the repeatability and reproducibility of a simplified evaluation grid of suture on inert material (Shirataki Konnyaku noodle) under smartphone magnification. MATERIAL AND METHODS: Ten students performed end-to-end suture on inert material with magnification via their smartphone. Each suture was filmed, and the videos were randomized. Each student was evaluated on each video three times over three consecutive days, using a simplified evaluation grid. Intra- and inter-observer agreement was evaluated on Concordance Correlation Coefficients. Values were assessed on Pearson's correlation coefficient. RESULTS: Intra-observer correlation was weak for 2 items (0.288 and 0.246) and moderate for the other 2 (0.419 and 0.529). Inter-observer correlation was weak for 3 items (0.344, 0.358, and 0.276) and close to zero for the other (0.034). CONCLUSION: This simplified evaluation grid for microsurgery training on inert material via smartphone was poorly repeatable and reproducible. Loss of certain items in the grid due to the use of inert material probably impaired relevance.

Microsurgical training in vein anastomoses: the use of systemic heparin in a rat model.

OBJECTIVE: To investigate whether the use of systemic heparin could be useful for vein microvascular anastomoses in microsurgical training on rats. DESIGN: Femoral end-to-end venous anastomoses were performed on both thighs of 40 wistar rats by two microsurgery trainees from October 2018 to February 2019 (80 anastomoses in total). We divided the rats into 2 groups of 20 specimens (40 femoral end-to-end anastomoses) each: group A received no heparin administration; group B received subcutaneous systemic heparin administration before starting dissection. We compared both vein patency after the procedures. RESULTS: Patency tests showed no difference between the two groups after 5 minutes. At the delayed test after 120 minutes, vein patency was significantly better in the systemic heparin group (85,0% vs 55,0%). Even though both trainees judged practicing on both groups very instructive, they found useful performing anastomoses when heparin was administrated. CONCLUSION: We suggest including the use of systemic heparin in microsurgery training programs, especially for the beginners. Systemic heparin administration in rat models is educative for trainees.

Development and Validation of a Laryngeal Microsurgery Simulation Training System for Otolaryngology Residents.

OBJECTIVE: This study aims to create a synthetic laryngeal microsurgery simulation model and training program; to assess its face, content, and construct validity; and to review the available phonomicrosurgery simulation models in the literature. STUDY DESIGN: Nonrandomly assigned control study. SETTING: Simulation training course for the otolaryngology residency program at Pontificia Universidad Católica de Chile. METHODS: Resident (postgraduate year 1 [PGY1]/PGY2) and expert groups were recruited. A laryngeal microsurgery synthetic model was developed. Nine tasks were designed and assessed through a set of programmed exercises with increasing difficulty, to fulfill 5 surgical competencies. Imperial College Surgical Assessment Device sensors applied to the participants' hands measured time and movements. The activities were video-recorded and blindly assessed by 2 laryngologists using a specific and global rating scale (SRS and GRS). A 5-point Likert survey assessing validity was completed by experts. RESULTS: Eighteen participants were recruited (14 residents and 4 experts). Experts performed significantly better than residents in the SRS (p = .003), and GRS (p = .004). Internal consistency was demonstrated for the SRS (α = .972, p < .001). Experts had a shorter execution time (p = .007), and path length with the right hand (p = .04). The left hand did not show significant differences. The survey assessing validity resulted in a median 36 out of 40 points score for face validity; and 43 out of 45 points score, for global content validity. The literature review revealed 20 available phonomicrosurgery simulation models, only 6 with construct validity. CONCLUSION: The face, content, and construct validity of the laryngeal microsurgery simulation training program were established. It could be replicated and incorporated into residents' curricula.

Hacia un programa inicial de formación estandarizado en microcirugía experimental para cirujanos pediátricos / Towards a standardized initial training program in experimental microsurgery for pediatric surgeons

Objetivo: Describimos un programa de formación básica en microcirugía y analizamos la curva de aprendizaje a través del proceso,incluyendo la mejora en los tiempos operatorios y en el resultado funcional del procedimiento. Material y métodos: Nuestro programa de aprendizaje incluyemodelos básicos, de transición y experimentales. Dentro del modeloexperimental se incluyeron: canulación de la vena de la cola, reseccióny anastomosis intestinal, disección, sección y anastomosis de la cava y laaorta. Se emplearon ratas Wistar (66,7% machos; 406,9 ± 38,9 gramos),el programa se adhirió al principio de las 3R y obtuvo la aprobación delcomité de bienestar animal. Resultados: l tiempo medio de canulación de la vena de la cola fuede 2.4 ± 1,2 minutos. El tiempo medio de resección intestinal y anastomosis yeyunocólica de 14.8 ± 2,7 minutos y 10.4 ± 3 minutos, respectivamente. Todas las anastomosis fueron funcionalmente válidas. El tiempomedio de la disección de vasos fue de 22,9 ± 7,7 minutos, la anastomosisde la arteria aorta de 17,2 ± 7,1 minutos, mientras que la anastomosisde la vena cava fue de 25,9 ± 7,3 minutos. El 66,7% de las anastomosisde la vena cava fueron funcionalmente válidas en comparación con el88,9% de la aorta. El tiempo requerido para todos los procedimientosdisminuyó después del tercer intento, excepto para las anastomosis devena cava, que se mantuvo similar en los 9 procedimientos. Conclusiones: Nuestro modelo demostró que los procedimientoseran adecuados para la progresión del entrenador en términos de tiempo quirúrgico y resultado funcional. La formación microquirúrgica sebeneficiaría de programas estandarizados para optimizar los resultados.(AU)

Objective: To describe a basic training program in microsurgery andto analyze the learning curve through the process, including improve-ment in operating times and functional outcome. Materials and methods: Our learning program included basic,transitional, and experimental models. The experimental model includedtail vein cannulation, intestinal resection and anastomosis, dissection,division and anastomosis of the cava and aorta. Wistar rats (66.7% male;406.9 ± 38.9 grams) were used. The program adhered to the 3R principleand obtained animal welfare committee approval. Results: Mean tail vein cannulation time was 2.4 ± 1.2 minutes.Mean intestinal resection and jejunocolic anastomosis time was14.8 ± 2.7 minutes and 10.4 ± 3 minutes, respectively. All anastomoseswere functionally valid. Mean vessel dissection time was 22.9 ± 7.7minutes, aortic artery anastomosis was 17.2 ± 7.1 minutes, and vena cavaanastomosis was 25.9 ± 7.3 minutes. 66.7% of vena cava anastomoseswere functionally valid vs. 88.9% for the aorta. The time required forall procedures decreased after the third attempt, except for vena cavaanastomoses, which remained similar in all 9 procedures. Conclusions: Our model demonstrated that the procedures weresuitable for trainer progression in terms of surgical time and functionaloutcome. Microsurgical training would benefit from standardized pro-grams to optimize results.(AU)

Racial/Ethnic and Gender Disparities Over the Last Decade Within Microsurgery and Craniofacial Fellowship Training.

BACKGROUND: Racial/ethnic and gender disparities persist in plastic surgery at nearly all levels of training, becoming more pronounced at each stage. Recent studies have demonstrated that the proportion of female plastic surgery residents has increased to nearly 40%, yet only 11% of full professors of plastic surgery are female. Other studies have identified severe declines in underrepresented minority plastic surgery representation between plastic surgery residents and academicians with only 1.6% of Black/African American and 4.9% of Hispanic/Latinx full professors of plastic surgery. Often, residents seek fellowship for advanced training before seeking an academic professorship. This study aims to describe the racial/ethnic and gender representation of microsurgery and craniofacial fellows. METHODS: Names and photos of graduated fellows for the past 10 years (2012-2021) were extracted from microsurgery and craniofacial fellowship Web sites. Using a 2-person evaluation method, race/ethnicity and gender were primarily determined by photographic and surname and verified, when possible, through online confirmation methods (articles, social media). Distributions were analyzed with descriptive statistics and compared with the US population. RESULTS: Among 30 microsurgery fellowships, 180 graduated fellows (52.7%) were identified, resulting in 66 female fellows (36.7%) and the following racial/ethnic distribution: 113 (62.8%) White, 49 (27.2%) Asian, 12 (6.7%) Hispanic/Latinx, and 6 (3.3%) Black/African American. Among 31 craniofacial fellowships, 136 graduated fellows (45.0%) were identified, resulting in 38 female fellows (27.9%) and the following racial/ethnic distribution: 75 (55.1%) White, 45 (33.1%) Asian, 8 (5.9%) Hispanic/Latinx, and 8 (5.9%) Black/African American. The intersection between race/ethnicity and gender revealed the most disproportionately low representation among Black women. Relative to the US population, Hispanic/Latinx (0.31-fold) and Black/African American (0.48-fold) fellows were underrepresented, White (0.90-fold) fellows were nearly equally represented, and Asian (5.42-fold) fellows are overrepresented relative to the US population. Furthermore, despite pursuing fellowships at a greater rate, Asian and Black fellows are not reaching adequate representation among academic plastic surgeons. CONCLUSION: This study demonstrates that female racial/ethnic minorities are disproportionately underrepresented among microsurgery and craniofacial fellowships. Efforts should be made to improve the recruitment of fellows of underrepresented backgrounds and thus improve the pipeline into academic careers.