REFERENCES

1. Breuing K, Butler CE, Ferzoco S, et al; Ventral Hernia Working Group. Incisional ventral hernias: review of the literature and recommendations regarding the grading and technique of repair. Surgery. 2010;148:544-58.

2. Rosen MJ, Krpata DM, Ermlich B, Blatnik JA. A 5-year clinical experience with single-staged repairs of infected and contaminated abdominal wall defects utilizing biologic mesh. Ann Surg. 2013;257:991-6.

3. Harris HW, Primus F, Young C, et al. Preventing recurrence in clean and contaminated hernias using biologic versus synthetic mesh in ventral hernia repair: the PRICE randomized clinical trial. Ann Surg. 2021;273:648-55.

4. Olavarria OA, Bernardi K, Dhanani NH, et al. Synthetic versus biologic mesh for complex open ventral hernia repair: a pilot randomized controlled trial. Surg Infect. 2021;22:496-503.

5. Carbonell AM, Criss CN, Cobb WS, Novitsky YW, Rosen MJ. Outcomes of synthetic mesh in contaminated ventral hernia repairs. J Am Coll Surg. 2013;217:991-8.

6. Slater NJ, Knaapen L, Bökkerink WJV, et al. Large contaminated ventral hernia repair using component separation technique with synthetic mesh. Plast Reconstr Surg. 2015;136:796e-805.

7. Warren J, Desai SS, Boswell ND, et al. Safety and efficacy of synthetic mesh for ventral hernia repair in a contaminated field. J Am Coll Surg. 2020;230:405-13.

8. Morris MP, Mellia JA, Christopher AN, et al. Ventral hernia repair with synthetic mesh in a contaminated field: a systematic review and meta-analysis. Hernia. 2021;25:1035-50.

9. Ellis R, Miller BT. Mesh selection in abdominal wall reconstruction: an update on biomaterials. Surg Clin North Am. 2023;103:1019-28.

10. Engelsman AF, van der Mei HC, Busscher HJ, Ploeg RJ. Morphological aspects of surgical meshes as a risk factor for bacterial colonization. Br J Surg. 2008;95:1051-9.

11. Engelsman AF, van der Mei HC, Ploeg RJ, Busscher HJ. The phenomenon of infection with abdominal wall reconstruction. Biomaterials. 2007;28:2314-27.

12. Ellis RC, Maskal SM, Messer N, et al. Short-term outcomes of heavyweight versus mediumweight synthetic mesh in a retrospective cohort of clean-contaminated and contaminated retromuscular ventral hernia repairs. Surg Endosc. 2024;38:4006-13.

13. Majumder A, Winder JS, Wen Y, Pauli EM, Belyansky I, Novitsky YW. Comparative analysis of biologic versus synthetic mesh outcomes in contaminated hernia repairs. Surgery. 2016;160:828-38.

14. Rosen MJ, Krpata DM, Petro CC, et al. Biologic vs synthetic mesh for single-stage repair of contaminated ventral hernias: a randomized clinical trial. JAMA Surg. 2022;157:293-301.

15. Siddiqui A, Lyons NB, Anwoju O, et al. Mesh type with ventral hernia repair: a systematic review and meta-analysis of randomized trials. J Surg Res. 2023;291:603-10.

16. DeNoto G 3rd, Ceppa EP, Pacella SJ, et al. 24-month results of the BRAVO study: a prospective, multi-center study evaluating the clinical outcomes of a ventral hernia cohort treated with OviTex® 1S permanent reinforced tissue matrix. Ann Med Surg. 2022;83:104745.

17. Ilahi ON, Velmahos G, Janis JE, et al. Prospective, multicenter study of antimicrobial-coated, noncrosslinked, acellular porcine dermal matrix (XenMatrix^TM AB Surgical Graft) for hernia repair in all centers for disease control and prevention wound classes: 24-month follow-up cohort. Ann Med Surg. 2023;85:1571-7.

18. Charleux-Muller D, Romain B, Boisson C, Velten M, Brigand C, Lejeune C. Cost-effectiveness analysis of resorbable biosynthetic mesh in contaminated ventral hernia repair. J Visc Surg. 2022;159:279-85.

19. Jacobsen G, DuCoin C. Biodegradable meshes in abdominal wall surgery. In: Novitsky Y, Editors. Hernia surgery. Springer, Cham; 2016. pp. 71-8.

20. Perrone G, Giuffrida M, Bonati E, Petracca GL, Catena F. Biosynthetic meshes in contaminated fields: where are we now? Hernia. 2023;27:765-80.

21. GORE® BIO-A® Tissue reinforcement - instructions for use. Available from: https://www.goremedical.com/products/bio-a-tissue. [Last accessed on 22 Sep 2025].

22. Claessen JJM, Timmer AS, Atema JJ, Boermeester MA. Outcomes of mid-term and long-term degradable biosynthetic meshes in single-stage open complex abdominal wall reconstruction. Hernia. 2021;25:1647-57.

23. Rosen MJ, Bauer JJ, Harmaty M, et al. Multicenter, prospective, longitudinal study of the recurrence, surgical site infection, and quality of life after contaminated ventral hernia repair using biosynthetic absorbable mesh: the COBRA study. Ann Surg. 2017;265:205-11.

24. Huang EY, Broderick RC, Spurzem GJ, et al. Long-term outcomes of PGA-TMC absorbable synthetic scaffold in both clean and contaminated ventral hernia repairs. Surg Endosc. 2024;38:2231-9.

25. Phasix^TM mesh - a resorbable mesh with resorbable hydrogel coating for soft tissue reconstruction - instructions for open and laparoscopic use. Available from: https://www.bd.com/content/dam/bd-assets/na/surgery/documents/instructions-for-use/Phasix-ST-E-IFU-with-hiatal-final.pdf. [Last accessed on 28 Sep 2025].

26. Layer T, Benammi S, Dubuisson V, et al. Incisional hernia repair with a slowly absorbable P4HB mesh: what happens after the mesh disappears? Hernia. 2023;27:387-94.

27. Van den Dop LM, Van Rooijen MMJ, Tollens T, et al. Five-year follow-up of a slowly resorbable biosynthetic P4HB Mesh (Phasix) in VHWG grade 3 incisional hernia repair. Ann Surg Open. 2023;4:e366.

28. Lake SP, Stoikes NFN, Badhwar A, Deeken CR. Contamination of hybrid hernia meshes compared to bioresorbable Phasix^TM Mesh in a rabbit subcutaneous implant inoculation model. Ann Med Surg. 2019;46:12-6.

29. Stoikes NFN, Scott JR, Badhwar A, Deeken CR, Voeller GR. Characterization of host response, resorption, and strength properties, and performance in the presence of bacteria for fully absorbable biomaterials for soft tissue repair. Hernia. 2017;21:771-82.

30. Molina C, Hussey GS, Liu A, Eriksson J, D’Angelo WA, Badylak SF. Role of 4-hydroxybutyrate in increased resistance to surgical site infections associated with surgical meshes. Biomaterials. 2021;267:120493.

31. Martin DP, Badhwar A, Shah DV, et al. Characterization of poly-4-hydroxybutyrate mesh for hernia repair applications. J Surg Res. 2013;184:766-73.

32. Transorb^TM self-gripping resorbable mesh - technique guide. Available from: https://www.medtronic.com/en-us/healthcare-professionals/products/hernia-repair/synthetic-mesh/transorb-self-gripping-resorbable-mesh.html. [Last accessed on 22 Sep 2025].

33. Vestberg R, Lecuivre J, Radlovic A, Payet E, Bayon Y, Bouré L. A novel self-gripping long-term resorbable mesh providing temporary support for open primary ventral and incisional hernia. J Mater Sci Mater Med. 2023;34:59.

34. Rodriguez-Quintero JH, Estrada A, Arias-Espinosa L, et al. Elective complex ventral hernia repair in contaminated fields: a propensity score-matched analysis of long-term quality of life and outcomes between different prostheses. Surgery. 2024;176:1668-75.

35. Rodriguez-Quintero JH, Romero-Velez G, Lima DL, Huang LC, Sreeramoju P, Malcher F. Permanent vs absorbable mesh for ventral hernia repair in contaminated fields: multicenter propensity-matched analysis of 1-year outcomes using the abdominal core health quality collaborative database. J Am Coll Surg. 2023;236:374-86.

36. Morales-Conde S, Hernández-Granados P, Tallón-Aguilar L, Verdaguer-Tremolosa M, López-Cano M. Ventral hernia repair in high-risk patients and contaminated fields using a single mesh: proportional meta-analysis. Hernia. 2022;26:1459-71.

37. Dumanian GA, Moradian S. Fascial closure: new surgery paradigms. Adv Surg. 2020;54:215-29.

38. Souza JM, Dumanian ZP, Gurjala AN, Dumanian GA. In vivo evaluation of a novel mesh suture design for abdominal wall closure. Plast Reconstr Surg. 2015;135:322e-30.

39. Lanier ST, Dumanian GA, Jordan SW, Miller KR, Ali NA, Stock SR. Mesh sutured repairs of abdominal wall defects. Plast Reconstr Surg Glob Open. 2016;4:e1060.

40. Dumanian GA, Lanier ST, Souza JM, et al. Mesh sutured repairs of contaminated incisional hernias. Am J Surg. 2018;216:267-73.

41. Dumanian GA. Suturable mesh demonstrates improved outcomes over standard suture in a porcine laparotomy closure model. Plast Reconstr Surg Glob Open. 2021;9:e3879.

42. Dumanian GA, Tulaimat A, Dumanian ZP. Experimental study of the characteristics of a novel mesh suture. Br J Surg. 2015;102:1285-92.

43. Scheiber CJ, Kurapaty SS, Goldman SM, Dearth CL, Liacouras PC, Souza JM. Suturable mesh better resists early laparotomy failure in a cyclic ball-burst model. Hernia. 2020;24:559-65.

44. Quattrone M, Moyer ED, Zolin SJ, et al. Short-term outcomes of mesh-suture repair in the treatment of ventral hernias: a single-center study. Surg Endosc. 2025;39:2129-35.

45. Hackenberger PN, Mittal M, Fronza J, Shapiro M. Duramesh registry study: short-term outcomes using mesh suture for abdominal wall closure. Front Surg. 2023;10:1321146.

46. Slater NJ, Montgomery A, Berrevoet F, et al. Criteria for definition of a complex abdominal wall hernia. Hernia. 2014;18:7-17.

47. DeLong CG, Crowell KT, Liu AT, et al. Staged abdominal wall reconstruction in the setting of complex gastrointestinal reconstruction. Hernia. 2024;28:97-107.

48. Petro CC, Rosen MJ. Fight or flight: the role of staged approaches to complex abdominal wall reconstruction. Plast Reconstr Surg. 2018;142:38S-44.