Improved Quantification of Cell Density in the Arterial Wall—A Novel Nucleus Splitting Approach Applied to 3D Two-Photon Laser-Scanning Microscopy

Laan, Koen W.F. van der; Reesink, Koen D.; Bruggen, Myrthe M. van der; Jaminon, Armand M. G.; Schurgers, Leon J.; Megens, Remco T. A.; Huberts, Wouter; Delhaas, Tammo; Spronck, Bart

doi:10.3389/fphys.2021.814434

Cited by 1 publication

(1 citation statement)

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“…A binary collagen mask was constructed from the image stack using voxels that exceeded a background threshold of 11.8% of the image intensity range. The sample’s centerline was determined by fitting a cylinder to this structure using a previously reported cylinder fitting method [24]. Radial positions for each voxel in this structure were determined with respect to the sample’s centerline while radial boundaries of the collagen layer were set to exclude the 1% smallest and largest voxel radial positions, as shown in Figure 2 .…”

Section: Methodsmentioning

confidence: 99%

Evaluating flash freezing for preservation of rat abdominal aorta for delayed biomechanical characterization

van der Laan,

Reesink,

Lambrichts

et al. 2023

Preprint

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Most studies investigating arterial stiffening use animal rather than human arteries. This is because human tissue becomes available in small amounts and at irregular times, which complicates planning of experimental work. Suitable tissue preservation methods for delayed biomechanical testing prevents the need for testing fresh tissue and alleviates some of the logistical challenges of human ex vivo studies. Therefore, the present study aimed to investigate whether the existing method of flash freezing and subsequent cryostorage provides is suitable for delaying the characterization of arterial biomechanics. Fresh and flash frozen abdominal aortas (n=16 and 14, respectively) were quasistatically and dynamically tested using a biaxial testing set-up with dynamic pressurization capabilities. The acquired biomechanical data was modeled using a constituent-based quasi-linear viscoelastic modeling framework, deriving directional stiffness parameters, individual constituent biomechanical contributions, and viscoelastic stiffening under dynamic pressurization conditions. Flash freezing reduced arterial wall thickness, increased circumferential stiffness, as well as reduced viscoelastic stiffening at higher pressures. These findings reflected those in the modeled contribution of collagen to arterial biomechanics, showing increased collagen load bearing at higher pressures. However, despite the above mentioned detectable changes, flash freezing did not alter the mechanical relation between elastin and collagen, maintaining a non-linear response to pressurization and stretch. Flash freezing may thus be suitable for studies requiring delayed characterization of passive arterial biomechanics, assuming care is taken to ascert that the impact of flash freezing on study groups can be approached as a systematic error.

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Section: Methodsmentioning

confidence: 99%