Assessing the combined effect of surface topography and substrate rigidity in human bone marrow stem cell cultures

Ribeiro, Sofia; Pugliese, Eugenia; Korntner, Stefanie; Fernandes, Emanuel M.; Gomes, Manuela E.; Reis, Rui L.; O’Riordan, Alan; Bayon, Yves; Zeugolis, Dimitrios I.

doi:10.1002/elsc.202200029

Cited by 3 publications

(5 citation statements)

References 85 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…[190] With respect to lineage commitment in appropriate media, high substrate rigidity (12 kPa) and surface topography (bidirectional grooves of 1-2 μm dimensionality) have been shown to favor osteogenic and chondrogenic differentiation, while low substrate rigidity (7 kPa) alone or in combination with surface topography (bidirectional grooves of 1-2 μm dimensionality) was shown to promote tenogenic and adipogenic differentiation. [191] This is in alignment with other studies, where stiffness was also considered as a more potent than topography MSC differentiation driving factor [192] and topography was considered more potent than rigidity regulator of cell adhesion, shape, and spreading. [193] It is also Table 3.…”

Section: Stiffness and Topography On Msc Responsesupporting

confidence: 88%

It Takes Two to Tango: Controlling Human Mesenchymal Stromal Cell Response via Substrate Stiffness and Surface Topography

Ribeiro,

Watigny,

Bayon

et al. 2023

Advanced NanoBiomed Research

Self Cite

View full text Add to dashboard Cite

Cells sense extracellular matrix‐induced biophysical signals, which are transduced into intracellular signaling cascades, and trigger a series of cell responses, including adhesion, migration, and lineage commitment. Traditionally, in in vitro context, monofactorial approaches are employed to control cell fate, despite the fact that in vivo cells are exposed simultaneously to a diverse range of signals. Herein, an overview of key mechanotransduction pathways is first provided. Conventional single‐factor and contemporary multifactorial methodologies, based on substrate rigidity and surface topography, are then reviewed to recapitulate in vitro the in vivo niche, in an attempt to elucidate the underlying mechanisms involved in human mesenchymal stromal cell‐material interactions.

show abstract

Section: Stiffness and Topography On Msc Responsesupporting

confidence: 88%

It Takes Two to Tango: Controlling Human Mesenchymal Stromal Cell Response via Substrate Stiffness and Surface Topography

Ribeiro,

Watigny,

Bayon

et al. 2023

Advanced NanoBiomed Research

Self Cite

View full text Add to dashboard Cite

show abstract

“…Through this mechanism, substrate stiffness influences the ultimate differentiation of mesenchymal stem cells, with cells tending to progress along a lineage that mirrors native tissues with similar mechanical properties (Evans et al, 2009; Guo et al, 2020; Ribeiro et al, 2022; Zigon‐Branc et al, 2019). In particular, mesenchymal stem cells demonstrate greater spreading on stiffer substrates, adopting the flattened, extended morphology of osteoblasts (Xia et al, 2022).…”

Section: Methods Of Mechanical Stimulation For Bone Repairmentioning

confidence: 99%

The potential role of mechanotransduction in the management of pediatric calvarial bone flap repair

Anderson,

Hersh,

Khan

2023

Biotech & Bioengineering

View full text Add to dashboard Cite

Pediatric patients suffering traumatic brain injuries may require a decompressive craniectomy to accommodate brain swelling by removing a portion of the skull. Once the brain swelling subsides, the preserved calvarial bone flap is ideally replaced as an autograft during a cranioplasty to restore protection of the brain, as it can reintegrate and grow with the patient during immature skeletal development. However, pediatric patients exhibit a high prevalence of calvarial bone flap resorption post‐cranioplasty, causing functional and cosmetic morbidity. This review examines possible solutions for mitigating pediatric calvarial bone flap resorption by delineating methods of stimulating mechanosensitive cell populations with mechanical forces. Mechanotransduction plays a critical role in three main cell types involved with calvarial bone repair, including mesenchymal stem cells, osteoblasts, and dural cells, through mechanisms that could be exploited to promote osteogenesis. In particular, physiologically relevant mechanical forces, including substrate deformation, external forces, and ultrasound, can be used as tools to stimulate bone repair in both in vitro and in vivo systems. Ultimately, combating pediatric calvarial flap resorption may require a combinatorial approach using both cell therapy and bioengineering strategies.

show abstract

“…Hydrostatic pressure (HP), fluid shear stress (FSS), compression, and stretching mechanical stimulation work together with the complex structure of ECM to affect cell fate 174 . Therefore, it is believed that researches on the combined effects of multiple physical cues can better simulate the microenvironment in vivo, thus promoting the osteogenic differentiation of cells 175 . Reinwald Y et al confirmed that intermittent hydrostatic pressure (IHP) (270 kPa) in combination with topographical cues (fiber alignment) could direct the fate of MSCs, and enhanced the effect of osteogenesis 174 .…”

Section: Biomaterials-induced Physicomechanical Stimuli Towards Mscsmentioning

confidence: 99%

“…As additional insights into the interaction between cells and ECM in recent years, it was found that the combination of matrix stiffness and nano- topography significantly affected the fate of cells as well 175 . After attaching to the random nanofibers, cells presented apparent stretching morphology and transformed mechanical signals into intracellular signals through cytoskeletal rearrangement, thus promoting osteogenic differentiation 174 .…”

Section: Biomaterials-induced Physicomechanical Stimuli Towards Mscsmentioning

confidence: 99%

“…After attaching to the random nanofibers, cells presented apparent stretching morphology and transformed mechanical signals into intracellular signals through cytoskeletal rearrangement, thus promoting osteogenic differentiation 174 . And this effect could be amplified by the combination with matrix stiffness 175 . Nevertheless, it is difficult to obtain the optimal stiffness and topography for osteogenesis simultaneously.…”

Section: Biomaterials-induced Physicomechanical Stimuli Towards Mscsmentioning

confidence: 99%

See 1 more Smart Citation

Integrating physicomechanical and biological strategies for BTE: biomaterials-induced osteogenic differentiation of MSCs

Shi¹,

Zhou²,

Wang³

et al. 2023

Theranostics

View full text Add to dashboard Cite

Large bone defects are a major global health concern. Bone tissue engineering (BTE) is the most promising alternative to avoid the drawbacks of autograft and allograft bone. Nevertheless, how to precisely control stem cell osteogenic differentiation has been a long-standing puzzle. Compared with biochemical cues, physicomechanical stimuli have been widely studied for their biosafety and stability. The mechanical properties of various biomaterials (polymers, bioceramics, metal and alloys) become the main source of physicomechanical stimuli. By altering the stiffness, viscoelasticity, and topography of materials, mechanical stimuli with different strengths transmit into precise signals that mediate osteogenic differentiation. In addition, externally mechanical forces also play a critical role in promoting osteogenesis, such as compression stress, tensile stress, fluid shear stress and vibration, etc. When exposed to mechanical forces, mesenchymal stem cells (MSCs) differentiate into osteogenic lineages by sensing mechanical stimuli through mechanical sensors, including integrin and focal adhesions (FAs), cytoskeleton, primary cilium, ions channels, gap junction, and activating osteogenic-related mechanotransduction pathways, such as yes associated proteins (YAP)/TAZ, MAPK, Rho-GTPases, Wnt/β-catenin, TGFβ superfamily, Notch signaling. This review summarizes various biomaterials that transmit mechanical signals, physicomechanical stimuli that directly regulate MSCs differentiation, and the mechanical transduction mechanisms of MSCs. This review provides a deep and broad understanding of mechanical transduction mechanisms and discusses the challenges that remained in clinical translocation as well as the outlook for the future improvements.

show abstract

Assessing the combined effect of surface topography and substrate rigidity in human bone marrow stem cell cultures

Cited by 3 publications

References 85 publications

It Takes Two to Tango: Controlling Human Mesenchymal Stromal Cell Response via Substrate Stiffness and Surface Topography

It Takes Two to Tango: Controlling Human Mesenchymal Stromal Cell Response via Substrate Stiffness and Surface Topography

The potential role of mechanotransduction in the management of pediatric calvarial bone flap repair

Integrating physicomechanical and biological strategies for BTE: biomaterials-induced osteogenic differentiation of MSCs

Contact Info

Product

Resources

About