REFERENCES

1. Hoffmann H, Köckerling F, Adolf D, et al. Analysis of 4,015 recurrent incisional hernia repairs from the Herniamed registry: risk factors and outcomes. Hernia 2021;25:61-75.

2. Kallinowski F, Gutjahr D, Harder F, et al. The grip concept of incisional hernia repair-dynamic bench test, CT abdomen with Valsalva and 1-Year clinical results. Front Surg 2021;8:602181.

3. Nessel R, Löffler T, Rinn J, et al. Primary and recurrent repair of incisional hernia based on biomechanical considerations to avoid mesh-related complications. Front Surg 2021;8:764470.

4. Kallinowski F, Ludwig Y, Löffler T, et al. Biomechanics applied to incisional hernia repair - considering the critical and the gained resistance towards impacts related to pressure. Clin Biomech 2021;82:105253.

5. Kallinowski F, Ludwig Y, Gutjahr D, et al. Biomechanical influences on mesh-related complications in incisional hernia repair. Front Surg 2021;8:763957.

6. Kallinowski F, Baumann E, Harder F, et al. Dynamic intermittent strain can rapidly impair ventral hernia repair. J Biomech 2015;48:4026-36.

7. Kallinowski F, Harder F, Gutjahr D, et al. Assessing the GRIP of ventral hernia repair: how to securely fasten DIS classified meshes. Front Surg 2017;4:78.

8. Kallinowski F, Gutjahr D, Vollmer M, Harder F, Nessel R. Increasing hernia size requires higher GRIP values for a biomechanically stable ventral hernia repair. Ann Med Surg 2019;42:1-6.

9. Romanowicz P, Muc A. Estimation of notched composite plates fatigue life using residual strength model calibrated by step-wise tests. Materials 2018;11:2180.

10. Zenner H, Hinkelmann K. 2017.Fatigue of components: August Wöhler (1819-1914): a historical review. DVM Sonderhefte, German Association for Material Research and Testing eV. ISBN: 978-3-9814516-6-5; Available from: https://onlinelibrary.wiley.com/doi/10.1002/stab.201900041. [Last accessed on 15 Jun 2023] (In German).

11. Kurrer KE. The history of the theory of structures: searching for equilibrium. In: Wiley, Ernst & Sohn, Berlin 2018 P. 1082. Available from: https://www.wiley.com/en-us/The+History+of+the+Theory+of+Structures%3A+Searching+for+Equilibrium%2C+2nd+Edition-p-9783433609132. [Last accessed on 15 Jun 2023].

12. Schütz W. Zur geschichte der schwingfestigkeit. Materwiss Werksttech 1993;24:203-232(In German).

13. Perren SM, Matter P, Rüedi R, Allgöwer M. Biomechanics of fracture healing after internal fixation. Surg Annu 1975;7:361-90.

14. Wale ME, Nesbitt DQ, Henderson BS, Fitzpatrick CK, Creechley JJ, Lujan TJ. Applying ASTM standards to tensile tests of musculoskeletal soft tissue: methods to reduce grip failures and promote reproducibility. J Biomech Eng 2021:143.

15. Soucasse A, Jourdan A, Edin L, Gillion JF, Masson C, Bege T. A better understanding of daily life abdominal wall mechanical solicitation: Investigation of intra-abdominal pressure variations by intragastric wireless sensor in humans. Med Eng Phys 2022;104:103813.

16. Moriyama S, Ogita F, Huang Z, et al. Intra-abdominal pressure during swimming. Int J Sports Med 2014;35:159-63.

17. Hackett DA, Chow CM. The Valsalva maneuver: its effect on intra-abdominal pressure and safety issues during resistance exercise. J Strength Cond Res 2013;27:2338-45.

18. Lesch C, Kugel F, Uhr K, et al. Cyclic pulse loads generate the new concept in abdominal wall reconstruction: suture closure. Mini-invasive Surg 2023;7:20.

19. Irwin RS, Dudiki N, French CL. CHEST Expert Cough Panel. Life-threatening and non-life-threatening complications associated with coughing: a scoping review. Chest 2020;158:2058-73.

20. Turner RD, Bothamley GH. How to count coughs? Counting by ear, the effect of visual data and the evaluation of an automated cough monitor. Respir Med 2014;108:1808-15.

21. Iqbal A, Haider M, Stadlhuber RJ, Karu A, Corkill S, Filipi CJ. A study of intragastric and intravesicular pressure changes during rest, coughing, weight lifting, retching, and vomiting. Surg Endosc 2008;22:2571-5.

22. Kawabata M, Shima N, Hamada H, Nakamura I, Nishizono H. Changes in intra-abdominal pressure and spontaneous breath volume by magnitude of lifting effort: highly trained athletes versus healthy men. Eur J Appl Physiol 2010;109:279-86.

23. Kawabata M, Shima N, Nishizono H. Regular change in spontaneous preparative behaviour on intra-abdominal pressure and breathing during dynamic lifting. Eur J Appl Physiol 2014;114:2233-9.

24. Blazek D, Stastny P, Maszczyk A, Krawczyk M, Matykiewicz P, Petr M. Systematic review of intra-abdominal and intrathoracic pressures initiated by the Valsalva manoeuvre during high-intensity resistance exercises. Biol Sport 2019;36:373-86.

25. Bower AF. Applied mechanics of solids. Available from: https://solidmechanics.org/contents.php 2019. [Last accessed on 14 Jun 2023].

26. König JA. Shakedown of elastic-plastic structures. Available from: https://shop.elsevier.com/books/shakedown-of-elastic-plastic-structures/mcgonagle/978-0-444-98979-6. [Last accessed on 14 Jun 2023].

27. Lesch C, Uhr K, Vollmer M, Raschidi R, Nessel R, Kallinowski F. Standardized suturing can prevent slackening or bursting suture lines in midline abdominal incisions and defects. Hernia 2022;26:1611-23.

28. Kallinowski F, Harder F, Silva TG, Mahn A, Vollmer M. Bridging with reduced overlap: fixation and peritoneal grip can prevent slippage of DIS class A meshes. Hernia 2017;21:455-67.

29. Szczesny SE, Caplan JL, Pedersen P, Elliott DM. Quantification of interfibrillar shear stress in aligned soft collagenous tissues via notch tension testing. Sci Rep 2015;5:14649.

30. Elmasry A, Azoti W, El-safty SA, Elmarakbi A. A comparative review of multiscale models for effective properties of nano- and micro-composites. Prog Mater Sci 2023;132:101022.

31. Spagnoli A, Terzano M, Brighenti R, Artoni F, Carpinteri A. How soft polymers cope with cracks and notches. Appl Sci 2019;9:1086.

32. Liu Z, Liao Z, Wang D, et al. Recent advances in soft biological tissue manipulating technologies. Chin J Mech Eng 2022;35:89.

33. Pierrat B, Nováček V, Avril S, Turquier F. Mechanical characterization and modeling of knitted textile implants with permanent set. J Mech Behav Biomed Mater 2021;114:104210.

34. Aryeetey OJ, Frank M, Lorenz A, Pahr DH. Fracture toughness determination of porcine muscle tissue based on AQLV model derived viscous dissipated energy. J Mech Behav Biomed Mater 2022;135:105429.

35. Bircher K, Zündel M, Pensalfini M, Ehret AE, Mazza E. Tear resistance of soft collagenous tissues. Nat Commun 2019;10:792.

36. Le Ruyet A, Yurtkap Y, Hartog FPJD, et al. Differences in biomechanics of abdominal wall closure with and without mesh reinforcement: A study in post mortem human specimens. J Mech Behav Biomed Mater 2020;105:103683.

37. Kallinowski F, Löffler T, Rinn J, Nessel R, Görich J, Wielpütz M. BJS-05 DIS class a meshes permit biomechanically strong reconstructions which are durable after a 3 year follow up. Br J Surg 2023;110:znad080.005.

38. Alcañiz P, Pérez J, Gutiérrez A, et al. Soft-Tissue simulation for computational planning of orthognathic surgery. J Pers Med 2021;11:982.

39. Alcañiz P, Vivo de Catarina C, Gutiérrez A, et al. Soft-tissue simulation of the breast for intraoperative navigation and fusion of preoperative planning. Front Bioeng Biotechnol 2022;10:976328.

40. Pachera P, Pavan PG, Todros S, Cavinato C, Fontanella CG, Natali AN. A numerical investigation of the healthy abdominal wall structures. J Biomech 2016;49:1818-23.

41. Tuset L, López-Cano M, Fortuny G, López JM, Herrero J, Puigjaner D. Virtual simulation of the biomechanics of the abdominal wall with different stoma locations. Sci Rep 2022;12:3545.

42. Pott PP, Schwarz ML, Gundling R, Nowak K, Hohenberger P, Roessner ED. Mechanical properties of mesh materials used for hernia repair and soft tissue augmentation. PLoS One 2012;7:e46978.

43. Münster S, Jawerth LM, Leslie BA, Weitz JI, Fabry B, Weitz DA. Strain history dependence of the nonlinear stress response of fibrin and collagen networks. Proc Natl Acad Sci U S A 2013;110:12197-202.

44. Licup AJ, Münster S, Sharma A, et al. Stress controls the mechanics of collagen networks. Proc Natl Acad Sci U S A 2015;112:9573-8.

45. Franz MG. The biology of hernia formation. Surg Clin North Am 2008;88:1-15, vii.

46. Leake M, Lai F, Grossmann T, Wigdor D, Lafreniere B. PatchProv: Supporting improvisational design practices for modern quilting. CHI '21: proceedings of the 2021 CHI Conference on Human Factors in Computing Systems. 2021. p. 1-17.

47. Sahoo S, DeLozier KR, Erdemir A, Derwin KA. Clinically relevant mechanical testing of hernia graft constructs. J Mech Behav Biomed Mater 2015;41:177-88.

48. Lauro E, Corridori I, Luciani L, et al. Stapled fascial suture: ex vivo modeling and clinical implications. Surg Endosc 2022;36:8797-806.

49. Barthel C, Halvachizadeh S, Gamble JG, Pape HC, Rauer T. Recreational skydiving-really that dangerous? Int J Environ Res Public Health 2023;20:1254.

50. Kallinowski F. Biomechanics of mesh repair of the herniated abdominal wall: requires some knowledge of stochastic processes. Available from: http://websurg.com/doi/lt03en24558. [Last accessed on 14 Jun 2023]