Rommel G. Bacabac scite author profile

Fibrin gels are responsible for the mechanical strength of blood clots, which are among the most resilient protein materials in nature. Here we investigate the physical origin of this mechanical behavior by performing rheology measurements on reconstituted fibrin gels. We find that increasing levels of shear strain induce a succession of distinct elastic responses that reflect stretching processes on different length scales. We present a theoretical model that explains these observations in terms of the unique hierarchical architecture of the fibers. The fibers are bundles of semiflexible protofibrils that are loosely connected by flexible linker chains. This architecture makes the fibers 100-fold more flexible to bending than anticipated based on their large diameter. Moreover, in contrast with other biopolymers, fibrin fibers intrinsically stiffen when stretched. The resulting hierarchy of elastic regimes explains the incredible resilience of fibrin clots against large deformations.

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Mechanosensation and transduction in osteocytes

Klein‐Nulend

Bakker

Bacabac

et al. 2013

Bone

408

319

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Cellulose and its derivatives: towards biomedical applications

et al. 2021

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Cellulose is the most abundant polysaccharide on Earth. It can be obtained from a vast number of sources, e.g. cell walls of wood and plants, some species of bacteria, and algae, as well as tunicates, which are the only known cellulose-containing animals. This inherent abundance naturally paves the way for discovering new applications for this versatile material. This review provides an extensive survey on cellulose and its derivatives, their structural and biochemical properties, with an overview of applications in tissue engineering, wound dressing, and drug delivery systems. Based on the available means of selecting the physical features, dimensions, and shapes, cellulose exists in the morphological forms of fiber, microfibril/nanofibril, and micro/nanocrystalline cellulose. These different cellulosic particle types arise due to the inherent diversity among the source of organic materials or due to the specific conditions of biosynthesis and processing that determine the consequent geometry and dimension of cellulosic particles. These different cellulosic particles, as building blocks, produce materials of different microstructures and properties, which are needed for numerous biomedical applications. Despite having great potential for applications in various fields, the extensive use of cellulose has been mainly limited to industrial use, with less early interest towards the biomedical field. Therefore, this review highlights recent developments in the preparation methods of cellulose and its derivatives that create novel properties benefiting appropriate biomedical applications.

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Mechanical loading and how it affects bone cells: The role of the osteocyte cytoskeleton in maintaining our skeleton

Klein‐Nulend

Bacabac²,

Bakker³

2012

eCM

278

217

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Mechanobiology of bone tissue

Klein‐Nulend

Bacabac

Mullender

2005

Pathologie Biologie

262

154

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Rommel G. Bacabac

Structural Hierarchy Governs Fibrin Gel Mechanics

Mechanosensation and transduction in osteocytes

Cellulose and its derivatives: towards biomedical applications

Mechanical loading and how it affects bone cells: The role of the osteocyte cytoskeleton in maintaining our skeleton

Mechanobiology of bone tissue

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