BACKGROUND: The adverse effects of annulotomy during lumbar discectomy have been increasingly recognized, and methods are developing to repair the annular defect. Biomechanically, the repair should retain the intra-nuclear pressure, which is doubtful using the current suture techniques. Therefore, a new suture technique was designed and tested to close a simpler type of annular incision. METHODS: A new suture technique, the modified purse-string suture, was introduced into a re-validated nonlinear finite element human disk model after creating a standard transverse slit incision, as well as two other suture techniques: either two simple sutures, or a horizontal crossed suture, and compared their contact pressure on the cleft contact surface. Then, porcine lumbar endplate-disk-endplate complexes with transverse slit incisions were repaired using the three techniques. Quantitative discomanometry was then applied to compare their leakage pressure, as a parameter of disk integrity. FINDINGS: In finite element model, the new technique created the greatest contact pressure along the suture range (the outer annulus), and generated a minimum contact pressure at the critical point, which was 68% and 55% higher than the other two suture techniques. In quantitative discomanometry, the new suture technique also had an average leakage pressure of 85% and 49% higher than the other two suture techniques. INTERPRETATION: The modified purse-string suture can generate higher contact pressure than the other two techniques at finite element analysis and in realistic animal models, which aids in retaining intra-discal pressure, and should be encouraged in clinical practice.
BACKGROUND: The adverse effects of annulotomy during lumbar discectomy have been increasingly recognized, and methods are developing to repair the annular defect. Biomechanically, the repair should retain the intra-nuclear pressure, which is doubtful using the current suture techniques. Therefore, a new suture technique was designed and tested to close a simpler type of annular incision. METHODS: A new suture technique, the modified purse-string suture, was introduced into a re-validated nonlinear finite element human disk model after creating a standard transverse slit incision, as well as two other suture techniques: either two simple sutures, or a horizontal crossed suture, and compared their contact pressure on the cleft contact surface. Then, porcine lumbar endplate-disk-endplate complexes with transverse slit incisions were repaired using the three techniques. Quantitative discomanometry was then applied to compare their leakage pressure, as a parameter of disk integrity. FINDINGS: In finite element model, the new technique created the greatest contact pressure along the suture range (the outer annulus), and generated a minimum contact pressure at the critical point, which was 68% and 55% higher than the other two suture techniques. In quantitative discomanometry, the new suture technique also had an average leakage pressure of 85% and 49% higher than the other two suture techniques. INTERPRETATION: The modified purse-string suture can generate higher contact pressure than the other two techniques at finite element analysis and in realistic animal models, which aids in retaining intra-discal pressure, and should be encouraged in clinical practice.
Authors: Clare C Guterl; Olivia M Torre; Devina Purmessur; Khyati Dave; Morakot Likhitpanichkul; Andrew C Hecht; Steven B Nicoll; James C Iatridis Journal: Tissue Eng Part A Date: 2014-05-06 Impact factor: 3.845
Authors: Michelle A Cruz; Steven McAnany; Nikita Gupta; Rose G Long; Philip Nasser; David Eglin; Andrew C Hecht; Svenja Illien-Junger; James C Iatridis Journal: J Biomech Eng Date: 2017-08-01 Impact factor: 2.097
Authors: Alexandra Alcántara Guardado; Alexander Baker; Andrew Weightman; Judith A Hoyland; Glen Cooper Journal: Bioengineering (Basel) Date: 2022-01-19
Authors: C C Guterl; E Y See; S B G Blanquer; A Pandit; S J Ferguson; L M Benneker; D W Grijpma; D Sakai; D Eglin; M Alini; J C Iatridis; S Grad Journal: Eur Cell Mater Date: 2013-01-02 Impact factor: 3.942