Substrate Modulus Directs Neural Stem Cell Behavior

Saha, Krishanu; Keung, Albert J.; Irwin, Elizabeth F.; Li, Yang; Little, Lauren; Schaffer, David V.; Healy, Kevin E.

doi:10.1529/biophysj.108.132217

Cited by 952 publications

(946 citation statements)

References 49 publications

Supporting

Mentioning

878

Contrasting

Unclassified

Order By: Relevance

“…Mammalian cells are commonly attached to their surrounding cells or extracellular matrix, which are associated with young's modulus in the range of 10 Pa-10 kPa (Yeung et al 2005;Saha et al 2008). Therefore to assess cellular responses, previous studies have used different elastic moduli of substrates (for instance, 42 Pa-280 kPa (Stroka & Aranda-Espinoza 2011a) and 10 Pa-10 kPa (Saha et al 2008)).…”

Section: Discussionmentioning

confidence: 99%

“…While numerous studies have confirmed the importance of surface chemistry in cell-substrate interaction for successful performance of implants or tissue engineered constructs, the impact of mechanical parameters of substrate, such as stiffness on cellular functions has only been studied in the past 10 years Yeung et al 2005;Saha et al 2008;Byfield et al 2009;Stroka & Aranda-Espinoza 2011a;Yeh et al 2012;Huang et al 2013;Ataollahi et al 2015).…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Regulation of Endothelial Cell Adherence and Elastic Modulus by Substrate Stiffness

Jalali

Tafazzoli-Shadpour

Haghighipour

et al. 2015

Cell Communication & Adhesion

View full text Add to dashboard Cite

Although substrate stiffness has been previously reported to affect various cellular aspects, such as morphology, migration, viability, growth, and cytoskeletal structure, its influence on cell adherence has not been well examined. Here, we prepared three soft, medium, and hard polyacrylamide (PAAM) substrates and utilized AFM to study substrate elasticity and also the adhesion and mechanical properties of endothelial cells in response to changing substrate stiffness. Maximum detachment force and cell stiffness were increased with increasing substrate stiffness. Maximum detachment force values were 0.28 ± 0.14, 0.94 ± 0.27, and 1.99 ± 0.59 nN while Young's moduli of cells were 218. 85 ± 38.73, 385.58 ± 131.67, and 933.20 ± 428.92 Pa for soft, medium, and hard substrates, respectively. Human umbilical vein endothelial cells (HUVECs) showed round to more spread shapes on soft to hard substrates, with the most organized and elongated actin structure on the hard hydrogel. Our results confirm the importance of substrate stiffness in regulating cell mechanics and adhesion for a successful cell therapy. ARTICLE HISTORY

show abstract

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Regulation of Endothelial Cell Adherence and Elastic Modulus by Substrate Stiffness

Jalali

Tafazzoli-Shadpour

Haghighipour

et al. 2015

Cell Communication & Adhesion

View full text Add to dashboard Cite

show abstract

“…Additional related studies have emphasized the critical role of hydrogel stiffness in skeletal muscle stem cell self-renewal 12 , neural stem cell behavior 13 and megakaryocyte poiesis 14 . 3D mechanical properties are similarly important in controlling adult stem cell fate in alginate hydrogels incorporating adhesive ligands 4 .…”

Section: Static Hydrogels That Mimic Biophysical Cuesmentioning

confidence: 99%

Moving from static to dynamic complexity in hydrogel design

2012

View full text Add to dashboard Cite

Hydrogels are water-swollen polymer networks that have found a range of applications from biological scaffolds to contact lenses. Historically, their design has consisted primarily of static systems and those that exhibit simple degradation. However, advances in polymer synthesis and processing have led to a new generation of dynamic systems that are capable of responding to artificial triggers and biological signals with spatial precision. These systems will open up new possibilities for the use of hydrogels as model biological structures and in tissue regeneration.H ydrogels are water-swollen polymer networks that have been used for many decades, with applications as varied as contact lenses and super-absorbant materials. As the field of biomedical engineering has developed, hydrogels have become a prime candidate for application as molecule delivery vehicles and as carriers for cells in tissue engineering, owing to their ability to mimic many aspects of the native cellular environment (for example, high water content, mechanical properties that match soft tissues). Traditional hydrogels, formed through the covalent and non-covalent crosslinking of polymer chains, were regarded as relatively inert materials, providing a simple biomimetic three-dimensional (3D) environment, either for tissue production by local resident cells or for positioning of cells delivered in vivo. However, the simplicity of these materials may have in fact hindered their application, restricting cellular interactions with the environment and preventing uniform extracellular matrix (ECM) production and proper tissue development. In addition, these materials were limited to modelling static environments and lacked the spatiotemporal dynamic properties relevant for complex tissue processes. Fortunately, during the last decade the concepts of hydrogel design and cellular interaction have evolved, shedding light on how they may control cell behaviour, particularly for tissue engineering applications.Hydrogels with a range of mechanical properties, and capable of incorporating a wide range of biologically relevant molecules, from individual functional groups to multidomain proteins, are currently in development 1 . In addition, hydrogels are being designed with spatial heterogeneity, to either replicate properties in native tissue structures or to produce constructs with distinct regionally specific cell behavior 2 . As a result, studies to date have clearly demonstrated the possibility of creating well-defined microenvironments with control over the 3D presentation of signals to cells 3 . However, recently there has been a focus on the concept of hydrogels that exhibit dynamic complexity. These materials should evolve with time and in response to

show abstract

“…In the last decade, matrix stiffness alone has been implicated in regulating cellular functions, such as contraction 3,4 , migration 5,6 , proliferation 7,8 and differentiation 9,10 . With this in mind, a variety of natural (for example, gelatin, collagen) and synthetic (for example, polyacrylamide) polymer systems were used in vitro to mimic the elasticity of native tissues, which varies significantly throughout the body (for example, brain: ~0.2-1 kPa (refs [11][12][13], muscle: ~10 kPa (ref. 10), osteoid: ~30-45 kPa (ref.…”

mentioning

confidence: 99%

Stiffening hydrogels to probe short- and long-term cellular responses to dynamic mechanics

2012

View full text Add to dashboard Cite

Biological processes are dynamic in nature, and growing evidence suggests that matrix stiffening is particularly decisive during development, wound healing and disease; yet, nearly all in vitro models are static. Here we introduce a step-wise approach, addition then lightmediated crosslinking, to fabricate hydrogels that stiffen (for example, ~3-30 kPa) in the presence of cells, and investigated the short-term (minutes-to-hours) and long-term (daysto-weeks) cell response to dynamic stiffening. When substrates are stiffened, adhered human mesenchymal stem cells increase their area from ~500 to 3,000 µm 2 and exhibit greater traction from ~1 to 10 kPa over a timescale of hours. For longer cultures up to 14 days, human mesenchymal stem cells selectively differentiate based on the period of culture, before or after stiffening, such that adipogenic differentiation is favoured for later stiffening, whereas osteogenic differentiation is favoured for earlier stiffening.

show abstract

Substrate Modulus Directs Neural Stem Cell Behavior

Cited by 952 publications

References 49 publications

Regulation of Endothelial Cell Adherence and Elastic Modulus by Substrate Stiffness

Regulation of Endothelial Cell Adherence and Elastic Modulus by Substrate Stiffness

Moving from static to dynamic complexity in hydrogel design

Stiffening hydrogels to probe short- and long-term cellular responses to dynamic mechanics

Contact Info

Product

Resources

About