W. Buerzle scite author profile

This study was directed to the measurement of the mechanical response of fetal membranes to physiologically relevant loading conditions. Characteristic mechanical parameters were determined and their relation to the microstructural constituents collagen and elastin as well as to the pyridinium cross-link concentrations analyzed. 51 samples from twelve fetal membranes were tested on a custom-built inflation device, which allows mechanical characterization within a multiaxial state of stress. Methods of nonlinear continuum mechanics were used to extract representative mechanical parameters. Established biochemical assays were applied for the determination of the collagen and elastin content. Collagen cross-link concentrations were determined by high-performance liquid chromatography measurements. The results indicate a distinct correlation between the mechanical parameters of high stretch stiffness and membrane tension at rupture and the biochemical data of collagen content and pyridinoline as well as deoxypyridinoline concentrations. No correlation was observed between the mechanical parameters and the elastin content. Moreover, the low stretch stiffness is, with a value of 105 ± 31 × 10(-3) N/ mm much higher for a biaxial state of stress compared to a uniaxial stress configuration. Determination of constitutive model equations leads to better predictive capabilities for a reduced polynomial hyperelastic model with only terms related to the second invariant, I 2, of the right Cauchy-Green deformation tensor. Relevant insights were obtained on the mechanical behavior of fetal membranes. Collagen and its cross-linking were shown to determine membrane's stiffness and strength for multiaxial stress states. Their nonlinear deformation behavior characterizes the fetal membranes as I 2 material.

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On the deformation behavior of human amnion

Buerzle¹,

Mazza²

2013

Journal of Biomechanics

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Mussel‐mimetic tissue adhesive for fetal membrane repair: a standardized ex vivo evaluation using elastomeric membranes

et al. 2011

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ObjectiveIatrogenic preterm premature rupture of membranes (iPPROM), the main complication of invasive interventions in the prenatal period, seriously limits the benefit of diagnostic or surgical prenatal procedures. This study aimed to evaluate preventive plugging of punctured fetal membranes in an ex vivo situation using a new mussel‐mimetic tissue adhesive (mussel glue) to inhibit leakage.MethodsA novel biomechanical test device that tests the closure of injured membranes under near‐physiological conditions was used. Mussel glue, a poly(ethylene glycol)‐based hydrogel, was used to seal membrane defects of up to 3 mm in mechanically well‐defined elastomeric membranes with three different degrees of stiffness.ResultsElastomeric test membranes were successfully employed for testing mussel glue under well‐defined conditions. Mussel glue plugs were distended by up to 94%, which translated to an improved sealing efficiency on elastomeric membranes with high stiffness. For the stiffest membrane tested, a critical burst pressure of 48 mbar (36 mmHg) was accomplished in this ex vivo setting.ConclusionsMussel glue appears to efficiently seal membrane defects under well‐standardized ex vivo conditions. As repaired membranes resist pressures measured in amniotic cavities, mussel glue might represent a novel sealing method for iatrogenic membrane defects. Copyright © 2011 John Wiley & Sons, Ltd.

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W. Buerzle

Mussel-mimetic tissue adhesive for fetal membrane repair: An ex vivo evaluation

Multiaxial mechanical behavior of human fetal membranes and its relationship to microstructure

On the deformation behavior of human amnion

Mussel‐mimetic tissue adhesive for fetal membrane repair: a standardized ex vivo evaluation using elastomeric membranes

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