The Role of Cadaver-Based Flap Course in Microsurgical Education and Practice Patterns of Attendees: A Survey Study

Saïd C. Azoury; Sammy Othman; David L. Colen; Robyn B. Broach; Ines Lin; Michael R. Zenn; Stephen J. Kovach; L. Scott Levin

doi:10.1055/s-0040-1716320

Journal of Reconstructive Microsurgery, Inhaltsverzeichnis

J Reconstr Microsurg 2021; 37(02): 154-160
DOI: 10.1055/s-0040-1716320

Original Article

The Role of Cadaver-Based Flap Course in Microsurgical Education and Practice Patterns of Attendees: A Survey Study

Saïd C. Azoury

¹Division of Plastic Surgery, University of Pennsylvania, Philadelphia, Pennsylvania

,

Sammy Othman

¹Division of Plastic Surgery, University of Pennsylvania, Philadelphia, Pennsylvania

,

David L. Colen

¹Division of Plastic Surgery, University of Pennsylvania, Philadelphia, Pennsylvania

,

Robyn B. Broach

¹Division of Plastic Surgery, University of Pennsylvania, Philadelphia, Pennsylvania

,

Ines Lin

¹Division of Plastic Surgery, University of Pennsylvania, Philadelphia, Pennsylvania

,

Michael R. Zenn

²Zenn Plastic Surgery, Raleigh, North Carolina

,

Stephen J. Kovach^*

¹Division of Plastic Surgery, University of Pennsylvania, Philadelphia, Pennsylvania

,

L. Scott Levin^*

¹Division of Plastic Surgery, University of Pennsylvania, Philadelphia, Pennsylvania

³Department of Orthopedic Surgery, University of Pennsylvania, Philadelphia, Pennsylvania

› Institutsangaben

Abstract

Background In 2017, our institution initiated a cadaver laboratory-based course dedicated to teaching reconstructive microsurgery indications, preoperative planning, and flap dissection. The goals of this study are to describe the demographics and experience of participants/instructors and to evaluate the learning objectives and effectiveness of the course.

Methods Penn Flap Course (PFC) participants were sent an anonymous survey at the inaugural PFC 2017. Then, in 2019, both instructors and participants were sent a more comprehensive survey. Surveys included questions regarding demographics, training background, experiences in practice and/or training, and course evaluation.

Results At PFC 2017, participant response rate was 25% (12/44), and the primary reason for attending the course was to observe and learn from instructor dissections (66.7%). At PFC 2019, the response rate was 77.3% (17/22) for faculty and 73.0% (35/48) for participants. Both in 2017 and 2019, the vast majority of participants reported perceived improvement in understanding of flap dissection principles across all anatomic domains (94.3%–100%). In 2019, when asked about their background experience, the majority of participants reported comfort performing arterial and venous anastomosis without supervision (71%–77%) and being least comfortable with head and neck (H&N) microsurgery (mean comfort level: 5.2/10). Half of the participants (e.g., residents) find the presence of a microsurgery fellow at their institution useful to their educational experience. Instructors with additional fellowship training in microsurgery reported performing a higher volume of free flaps per week (7 vs. 2.3) and per year (94.2 vs. 27.8; p < 0.05 for both) and trend toward performing more H&N reconstruction (p = 0.057).

Conclusion Participants feel least comfortable with H&N microsurgical reconstruction. Surgical faculty with microsurgical fellowship training performs greater volume of microsurgical cases with a trend toward more H&N reconstruction. A cadaver/lecture-based flap course is an effective way to improve participants' perceived confidence and understanding of complex flap and microsurgical reconstructive procedures.

Keywords

education - cadaver - flap course

Volltext

Referenzen

References
1 Tamai S. History of microsurgery. Plast Reconstr Surg 2009; 124 (06) e282-e294
2 Ko JWK, Lorzano A, Mirarchi AJ. Effectiveness of a microvascular surgery training curriculum for orthopaedic surgery residents. J Bone Joint Surg Am 2015; 97 (11) 950-955
3 Rodriguez JR, Yañez R, Cifuentes I, Varas J, Dagnino B. Microsurgery workout: a novel simulation training curriculum based on nonliving models. Plast Reconstr Surg 2016; 138 (04) 739e-747e
4 Luginbuhl AJ, Pribitkin EA, Krein H, Heffelfinger RN. Assessment of microvascular anastomosis training in otolaryngology residencies: survey of United States program directors. Otolaryngol Head Neck Surg 2010; 143 (05) 633-636
5 Dumestre D, Yeung JK, Temple-Oberle C. Evidence-based microsurgical skill-acquisition series part 1: validated microsurgical models: a systematic review. J Surg Educ 2014; 71 (03) 329-338
6 Mueller MA, Pourtaheri N, Evans GRD. Microsurgery training resource variation among US integrated plastic surgery residency programs. J Reconstr Microsurg 2019; 35 (03) 176-181
7 Al-Bustani S, Halvorson EG. Status of microsurgical simulation training in plastic surgery a survey of United States program directors. Ann Plast Surg 2016; 76 (06) 713-716
8 Krähenbühl SM, Čvančara P, Stieglitz T. et al. Return of the cadaver: key role of anatomic dissection for plastic surgery resident training. Medicine (Baltimore) 2017; 96 (29) e7528
9 Turner AJ, Mellington A, Ali F. Fresh cadaver dissection for training in plastic surgery. Br J Plast Surg 2005; 58 (05) 742-743
10 Chouari TAM, Lindsay K, Bradshaw E. et al. An enhanced fresh cadaveric model for reconstructive microsurgery training. Eur J Plast Surg 2018; 41 (04) 439-446
11 Bancroft GN, Basu CB, Leong M, Mateo C, Hollier Jr LH, Stal S. Outcome-based residency education: teaching and evaluating the core competencies in plastic surgery. Plast Reconstr Surg 2008; 121 (06) 441e-448e
12 Reed AB, Crafton C, Giglia JS, Hutto JD. Back to basics: use of fresh cadavers in vascular surgery training. Surgery 2009; 146 (04) 757-762 , discussion 762–763
13 Grober ED, Elterman DS, Jewett MAS. Fellow or foe: the impact of fellowship training programs on the education of Canadian urology residents. Can Urol Assoc J 2008; 2 (01) 33-37
14 Serletti JM, Deuber MA, Guidera PM. et al. Comparison of the operating microscope and loupes for free microvascular tissue transfer. Plast Reconstr Surg 1995; 95 (02) 270-276
15 Stranix JT, Azoury SC, Lee Z-H. et al. Matched comparison of microsurgical anastomoses performed with loupe magnification versus operating microscope in traumatic lower extremity reconstruction. Plast Reconstr Surg 2020; 145 (01) 235-240
16 Ross DA, Ariyan S, Restifo R, Sasaki CT. Use of the operating microscope and loupes for head and neck free microvascular tissue transfer: a retrospective comparison. Arch Otolaryngol Head Neck Surg 2003; 129 (02) 189-193
17 Pannucci CJ, Basta MN, Kovach SJ, Kanchwala SK, Wu LC, Serletti JM. Loupes-only microsurgery is a safe alternative to the operating microscope: an analysis of 1,649 consecutive free flap breast reconstructions. J Reconstr Microsurg 2015; 31 (09) 636-642
18 Kozak GM, Katzel EB, Rose JF, Nathan SL, Wu LC. An analysis of specialty-specific microsurgical head and neck reconstruction: a look at a single institution and national trends over a decade. Ann Plast Surg 2020; 84 (04) 413-417
19 Lee Z-H, Daar DA, Jacobson AS, Levine JP. The decline of head and neck reconstruction in plastic surgery: where do we go from here?. Plast Reconstr Surg 2020; 145 (02) 467e-468e
20 Satterwhite T, Son J, Carey J. et al. Microsurgery education in residency training: validating an online curriculum. Ann Plast Surg 2012; 68 (04) 410-414
21 Theman TA, Labow BI. Is there bias against simulation in microsurgery training?. J Reconstr Microsurg 2016; 32 (07) 540-545
22 Evgeniou E, Walker H, Gujral S. The role of simulation in microsurgical training. J Surg Educ 2018; 75 (01) 171-181
23 Messmer C, Kellogg RT, Zhang Y. et al. A technique to perfuse cadavers that extends the useful life of fresh tissues: the Duke experience. Anat Sci Educ 2010; 3 (04) 191-194