The biology behind fascial defects and the use of implants in pelvic organ prolapse repair

Deprest, Jan; Zheng, Fang; Konstantinovic, Maja; Spelzini, Federico; Claerhout, Filip; Steensma, Anneke B.; Ozog, Yves; Ridder, Dirk De

doi:10.1007/s00192-006-0101-2

Cited by 100 publications

(75 citation statements)

References 52 publications

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“…This is not without an impact on strength, as non-degraded Pelvicol implants are twice as strong as degraded Pelvicol implants of similar thickness (234. 4 Occasional degradation is in accordance with earlier experiments by Claerhout et al [18] and clinical experience [25] , and has remained unexplained so far. Possible 'local' factors such as infection or a poor batch quality were considered.…”

Section: Discussionsupporting

confidence: 76%

“…Animal models do not mimic the effect of live events leading to prolapse, nor can implants be exposed to similar physical forces present in patients [4] . Further, some species, like rabbits, have a difference in collagen metabolism which may interfere with the results [27] .…”

Section: Discussionmentioning

confidence: 99%

“…This way, the implants (2.0 ! 3.5 cm) had dimensions 0.25 cm larger than the defect in all directions ('overlay' technique) [4] . All materials were hydrated for 10 min in sterile saline prior to implantation.…”

Section: Methodsmentioning

confidence: 99%

“…The lifetime risk of undergoing operative repair for prolapse by the age of 80 is 11.1% with recurrence rates of up to 29% [1][2][3] . Due to the host's inherent insufficient connective tissue quality, the use of autologous tissue in pelvic organ prolapse repair may account for some of the high recurrence rate [4] . To reduce this, implant materials have been proposed because they may reinforce the weakened tissue by incorporation at the treatment site.…”

Section: Introductionmentioning

confidence: 99%

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Porous Acellular Porcine Dermal Collagen Implants to Repair Fascial Defects in a Rat Model: Biomechanical Evaluation up to 180 Days

Ozog¹,

Konstantinovic²,

Zheng³

et al. 2009

Gynecol Obstet Invest

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Aim: To investigate the biomechanical properties of porous collagen matrices in a rat abdominal wall defect model. Study Design: 112 rats were implanted with non-cross-linked InteXèn LP, cross-linked Pelvicol, and two investigational acellular collagen matrices (ACMs) sterilized either with ethylene oxide (ACM ETO) or γ-irradiation (ACM GI). After 14, 30, 90 and 180 days, 7 animals per group were sacrificed to document adhesions, herniation, infection, stress resistance and histology. Results: The 2 sterilization methods did not cause measurable differences between ACMs. Pelvicol was more resistant than ACMs but showed degradation at 90 days without loss of strength. InteXèn LP became remodeled as a thin fibrous scar and was more resistant at all time points; however, some animals developed bulging. Conclusions: Non-cross-linked InteXèn LP became remodeled by 180 days with remarkable stress resistance. Despite cross-linking Pelvicol showed degradation. Comparable but investigational ACM explants were less resistant without morphologic differences to explain this.

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Section: Discussionsupporting

confidence: 76%

Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Porous Acellular Porcine Dermal Collagen Implants to Repair Fascial Defects in a Rat Model: Biomechanical Evaluation up to 180 Days

Ozog¹,

Konstantinovic²,

Zheng³

et al. 2009

Gynecol Obstet Invest

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“…In line with previous studies examining several commercially available mesh types [20,21], both our new meshes and the PP meshes showed contraction at all time points. Common causes for pain and tissue erosion are mesh folding and contraction after implantation, hence this should be avoided in human surgery [22]. Biomechanical properties of explanted samples were analysed using uniaxial tensile testing.…”

Section: Discussionmentioning

confidence: 99%

A preclinical evaluation of polypropylene/polylacticacid hybrid meshes for fascial defect repair using a rat abdominal hernia model

Dirnagl

Teuff

Huberlant

et al. 2017

Geburtshilfe Und Frauenheilkunde

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ObjectivesSynthetic mesh surgery for both abdominal and urogenital hernia repair is often unsatisfactory in the long-term due to postoperative complications. We hypothesized that a semidegradable mesh hybrid may provide more appropriate biocompatibility with comparable mechanical properties. The aim was to compare its in vivo biocompatibility with a commercial polypropylene (PP) mesh. Methods72 rats were randomly allocated to either our new composite mesh (monofilament PP mesh knitted with polylactic-acid-fibers (PLA)) or to a commercially available PP mesh that was used as a control. 15, 90, and 180 days after implantation into the rat abdomen mesh tissue complexes were analysed for erosion, contraction, foreign body reaction, tissue integration and biomechanical properties. ResultsNo differences were seen in regard to clinical parameters including erosion, contraction or infection rates between the two groups. Biomechanical properties including breaking load, stiffness and deformation did not show any significant differences between the different materials at any timepoint. Macrophage staining did not reveal any significant differences between the two groups or between timepoints either. In regard to collagen I there was significantly less collagen I in the PP group compared to the PP/ PLA group at day 180. Collagen III did not show any significant differences at any timepoint between the two groups.

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Endometrial mesenchymal stromal cell and tissue engineering for pelvic organ prolapse repair

Gurung

Werkmeister

Gargett

2016

The Biology and Therapeutic Application of Mesenchymal Cells

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The biology behind fascial defects and the use of implants in pelvic organ prolapse repair

Cited by 100 publications

References 52 publications

Porous Acellular Porcine Dermal Collagen Implants to Repair Fascial Defects in a Rat Model: Biomechanical Evaluation up to 180 Days

Porous Acellular Porcine Dermal Collagen Implants to Repair Fascial Defects in a Rat Model: Biomechanical Evaluation up to 180 Days

A preclinical evaluation of polypropylene/polylacticacid hybrid meshes for fascial defect repair using a rat abdominal hernia model

Endometrial mesenchymal stromal cell and tissue engineering for pelvic organ prolapse repair

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