| 1. |
- Möller, Per Werner, et al.
(författare)
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The Effects of Vasoconstriction And Volume Expansion on Veno-Arterial ECMO Flow
- 2019
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Ingår i: Shock. - 1073-2322. ; 51:5, s. 650-658
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Tidskriftsartikel (refereegranskat)abstract
- Veno-arterial extracorporeal membrane oxygenation (VA-ECMO) is gaining widespread use in the treatment of severe cardiorespiratory failure. Blood volume expansion is commonly used to increase ECMO flow (QECMO), with risk of positive fluid balance and worsening prognosis. We studied the effects of vasoconstriction on recruitment of blood volume as an alternative for increasing QECMO, based on the concepts of venous return.In a closed chest, centrally cannulated porcine preparation (n=9) in ventricular fibrillation and VA-ECMO with vented left atrium, mean systemic filling pressure (MSFP), and venous return driving pressure (VRdP) were determined in Euvolemia, during Vasoconstriction (norepinephrine 0.05, 0.125, and 0.2μg/kg/min) and after Volume Expansion (3 boluses of 10mL/kg Ringer's lactate). Maximum achievable QECMO was examined.Vasoconstriction and Volume Expansion both increased maximum achievable QECMO, delivery of oxygen (DO2), and MSFP, but right atrial pressure increased in parallel. VRdP did not change. The vascular elastance curve was shifted to the left by Vasoconstriction, with recruitment of stressed volume. It was shifted to the right by Volume Expansion with direct expansion of stressed volume. Volume Expansion decreased resistance to venous return and pump afterload.In a circulation completely dependent on ECMO support, maximum achievable flow directly depended on the vascular factors governing venous return-i.e., closing conditions, stressed vascular volume and the elastance and resistive properties of the vasculature. Both treatments increased maximum achievable ECMO flow at stable DO2, via increases in stressed volume by different mechanisms. Vascular resistance and pump afterload decreased with Volume Expansion.
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| 2. |
- Tsolaki, Elena, et al.
(författare)
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Multiscale multimodal characterization and simulation of structural alterations in failed bioprosthetic heart valves
- 2023
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Ingår i: Acta Biomaterialia. - 1878-7568 .- 1742-7061. ; 169, s. 138-154
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Tidskriftsartikel (refereegranskat)abstract
- Calcific degeneration is the most frequent type of heart valve failure, with rising incidence due to the ageing population. The gold standard treatment to date is valve replacement. Unfortunately, calcification oftentimes re-occurs in bioprosthetic substitutes, with the governing processes remaining poorly understood. Here, we present a multiscale, multimodal analysis of disturbances and extensive mineralisation of the collagen network in failed bioprosthetic bovine pericardium valve explants with full histoanatomical context. In addition to highly abundant mineralized collagen fibres and fibrils, calcified micron-sized particles previously discovered in native valves were also prevalent on the aortic as well as the ventricular surface of bioprosthetic valves. The two mineral types (fibres and particles) were detectable even in early-stage mineralisation, prior to any macroscopic calcification. Based on multiscale multimodal characterisation and high-fidelity simulations, we demonstrate that mineral occurrence coincides with regions exposed to high haemodynamic and biomechanical indicators. These insights obtained by multiscale analysis of failed bioprosthetic valves serve as groundwork for the evidence-based development of more durable alternatives. Statement of significance: Bioprosthetic valve calcification is a well-known clinically significant phenomenon, leading to valve failure. The nanoanalytical characterisation of bioprosthetic valves gives insights into the highly abundant, extensive calcification and disorganization of the collagen network and the presence of calcium phosphate particles previously reported in native cardiovascular tissues. While the collagen matrix mineralisation can be primarily attributed to a combination of chemical and mechanical alterations, the calcified particles are likely of host cellular origin. This work presents a straightforward route to mineral identification and characterization at high resolution and sensitivity, and with full histoanatomical context and correlation to hemodynamic and biomechanical indicators, hence providing design cues for improved bioprosthetic valve alternatives.
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