Home About us Contact
|
Home About us Contact | ||
|
|
||
Traction Forces (traction + force)
Selected AbstractsAlpha-smooth muscle actin expression enhances cell traction forceCYTOSKELETON, Issue 4 2007Jianxin Chen Abstract Using an established corneal stromal cell differentiation model, we manipulated ,-smooth muscle actin (,-SMA) protein expression levels in fibroblasts by treating them with TGF-,1, bFGF, TGF-, type I receptor inhibitor (SB-431542), and siRNA against ,-SMA. The corresponding cell traction forces (CTFs) were determined by cell traction force microscopy. With all these treatments, we found that ,-SMA is not required for CTF induction, but its expression upregulates CTF. This upregulation involves the modification of stress fibers but does not appear to relate to non-muscle myosin II expression or ,-actin expression. Moreover, there exists a linear relationship between ,-SMA protein expression level and CTF magnitude. Finally, CTFs were found to vary among a population of myofibroblasts, suggesting that ,-SMA protein expression levels of individual cells also vary. Cell Motil. Cytoskeleton 2007. © 2006 Wiley-Liss, Inc. [source] Perugia urodynamic method of analysis (PUMA): A new advanced method of urodynamic analysis applied clinically and compared with other advanced methodsNEUROUROLOGY AND URODYNAMICS, Issue 3 2003Massimo Porena Abstract Aims The aim of this study is to compare PUMA curves with different pathologic conditions causing bladder dysfunction in 158 men and 83 women. Methods PUMA results in terms of bladder outlet obstruction and detrusor contractility were compared in 92 men with benign prostatic hypertrophy (BPH) and pves,pdet (i.e., pabd,0) with the results of the urodynamics operator's opinion, the provisional International Continence Society method, Abrams and Griffith's diagram, urethral resistence factor (URA), Schäfer's diagram, and Watt factor. PUMA curves correlated reliably with different pathologic conditions such as obstructive BPH, orthotopic bladder, cystocele, the neurological bladder, and bladder diverticulum. Statistical analysis indicated excellent agreement between PUMA and URA; agreement with other methods was good in cases of obstruction and nonobstruction. In doubtful cases, as diagnosed by standard methods, PUMA agreed only with the Abrams and Griffith's diagram. PUMA and Wmax were in good agreement on detrusor con traction force. Agreement between PUMA and Schäfer's diagram was excellent for patients with detrusor hypercontractility and good for patients with detrusor hypocontractility and normocontractility. PUMA is the only method applicable to women. It is easy to perform. When integrated with other diagnostic tests, it provides realistic data for diagnosis, medical or surgical therapy, and outcome. Neurourol. Urodynam. 22:206,222, 2003. © 2003 Wiley-Liss, Inc. [source] Neutrophils display biphasic relationship between migration and substrate stiffnessCYTOSKELETON, Issue 6 2009Kimberly M. Stroka Abstract Neutrophils are one type of migrating cell in the body's innate immune system and are the first line of defense against inflammation or infection. While extensive work exists on the effect of adhesive proteins on neutrophil motility, little is known about how neutrophil motility is affected by the mechanical properties of their physical environment. This study investigated the effects of substrate stiffness on the morphology, random motility coefficient, track speed (v), spreading area, and distribution of turning angles of neutrophils during chemokinesis. Human neutrophils were plated onto polyacrylamide gels of varying stiffness, ranging from 3 to 13 kPa, and coated with the extracellular matrix protein fibronectin, and timelapse images were taken with phase contrast microscopy. Our results show a biphasic behavior between neutrophil motility and substrate stiffness, with the optimum stiffness for motility depending on the concentration of fibronectin on the surface of the gel. On 100 ,g/mL fibronectin, the optimum stiffness is 4 kPa (v = 6.9 ± 0.6 ,m/min) while on 10 ,g/mL fibronectin, the optimum stiffness increases to 7 kPa (v = 4.5 ± 2.0 ,m/min). This biphasic behavior most likely arises because neutrophils on soft gels are less adherent, preventing production of traction forces, while neutrophils on stiff gels adhere strongly, resulting in decreased migration. At intermediate stiffness, however, neutrophils can attain optimal motility as a function of extracellular matrix coating. Cell Motil. Cytoskeleton 2009. © 2009 Wiley-Liss, Inc. [source] Development of micropost force sensor array with culture experiments for determination of cell traction forcesCYTOSKELETON, Issue 7 2007Bin Li Abstract Cell traction forces (CTFs) are critical for cell motility and cell shape maintenance. As such, they play a fundamental role in many biological processes such as angiogenesis, embryogenesis, inflammation, and wound healing. To determine CTFs at the sub-cellular level with high sensitivity, we have developed high density micropost force sensor array (MFSA), which consists of an array of vertically standing poly(dimethylsiloxane) (PDMS) microposts, 2 ,m in diameter and 6 ,m in height, with a center-to-center distance of 4 ,m. In combination with new image analysis algorithms, the MFSA can achieve a spatial resolution of 40 nm and a force sensitivity of 0.5 nN. Culture experiments with various types of cells showed that this MFSA technology can effectively determine CTFs of cells with different sizes and traction force magnitudes. Cell Motil. Cytoskeleton 2007. © 2007 Wiley-Liss, Inc. [source] Cell distribution of stress fibres in response to the geometry of the adhesive environmentCYTOSKELETON, Issue 6 2006Manuel Théry Abstract Cells display a large variety of shapes when plated in classical culture conditions despite their belonging to a common cell type. These shapes are transitory, since cells permanently disassemble and reassemble their cytoskeleton while moving. Adhesive micropatterns are commonly used to confine cell shape within a given geometry. In addition the micropattern can be designed so as to impose cells to spread upon adhesive and nonadhesive areas. Modulation of the pattern geometry allows the analysis of the mechanisms governing the determination of cell shape in response to external adhesive conditions. In this study, we show that the acquisition of cell shape follows two stages where initially the cell forms contact with the micropattern. Here, the most distal contacts made by the cell with the micropattern define the apices of the cell shape. Then secondly, the cell borders that link two apices move so as to minimise the distance between the two apices. In these cell borders, the absence of an underlying adhesive substrate is overcome by stress fibres forming between the apices, which in turn are marked by an accumulation of focal adhesions. By inhibiting myosin function, cell borders on nonadhesive zones become more concave, suggesting that the stress fibres work against the membrane tension in the cell border. Moreover, this suggested that traction forces are unevenly distributed in stationary, nonmigrating, cells. By comparing the stress fibres in cells with one, two, or three nonadherent cell borders it was reasoned that stress fibre strength is inversely proportional to number. We conclude that cells of a given area can generate the same total sum of tractional forces but that these tractional forces are differently spaced depending on the spatial distribution of its adherence contacts. Cell Motil. Cytoskeleton 2006. © 2006 Wiley-Liss, Inc. [source] Interactions between the L1 cell adhesion molecule and ezrin support traction-force generation and can be regulated by tyrosine phosphorylationJOURNAL OF NEUROSCIENCE RESEARCH, Issue 12 2008Takeshi Sakurai Abstract An Ig superfamily cell-adhesion molecule, L1, forms an adhesion complex at the cell membrane containing both signaling molecules and cytoskeletal proteins. This complex mediates the transduction of extracellular signals and generates actin-mediated traction forces, both of which support axon outgrowth. The L1 cytoplasmic region binds ezrin, an adapter protein that interacts with the actin cytoskeleton. In this study, we analyzed L1,ezrin interactions in detail, assessed their role in generating traction forces by L1, and identified potential regulatory mechanisms controlling ezrin,L1 interactions. The FERM domain of ezrin binds to the juxtamembrane region of L1, demonstrated by yeast two-hybrid interaction traps and protein binding analyses in vitro. A lysine-to-leucine substitution in this domain of L1 (K1147L) shows reduced binding to the ezrin FERM domain. Additionally, in ND7 cells, the K1147L mutation inhibits retrograde movement of L1 on the cell surface that has been linked to the generation of the traction forces necessary for axon growth. A membrane-permeable peptide consisting of the juxtamembrane region of L1 that can disrupt endogenous L1,ezrin interactions inhibits neurite extension of cerebellar cells on L1 substrates. Moreover, the L1,ezrin interactions can be modulated by tyrosine phosphorylation of the L1 cytoplasmic region, namely, Y1151, possibly through Src-family kinases. Replacement of this tyrosine together with Y1176 with either aspartate or phenylalanine changes ezrin binding and alters colocalization with ezrin in ND7 cells. Collectively, these data suggest that L1,ezrin interactions mediated by the L1 juxtamembrane region are involved in traction-force generation and can be regulated by the phosphorylation of L1. © 2008 Wiley-Liss, Inc. [source] The ,sacral hand wedge': a cause of arrest of descent of the fetal head during vacuum assisted deliveryBJOG : AN INTERNATIONAL JOURNAL OF OBSTETRICS & GYNAECOLOGY, Issue 9 2002Aldo Vacca During a study of 108 vacuum assisted deliveries, a fetal hand was detected in the pelvic space between the head and maternal sacrum in seven of the procedures. The larger presenting diameters resulting from the compound fetal presentations were reflected in a greater number of pulls and higher traction forces recorded during the deliveries. In all cases, extraction of the hand facilitated the completion of birth without causing serious injury to the fetus or maternal perineum. It is recommended that a digital examination to detect the presence of a fetal hand in the sacral space should become a part of standard vacuum delivery practice. [source] A Theoretical Description of Elastic Pillar Substrates in Biophysical ExperimentsCHEMPHYSCHEM, Issue 8 2005Camilla Mohrdieck Dr. Abstract Arrays of elastic pillars are used in biophysical experiments as sensors for traction forces. The evaluation of the forces can be complicated if they are coupled to the pillar displacements over large distances. This is the case if many of the pillars are interconnected by elastic linkages as, for example, in fiber networks that are grown on top of pillars. To calculate the traction forces in such a network, we developed a set of nonlinear inhomogeneous equations relating the forces in the linking elements to the resulting pillar deflections. We chose a homogeneous, activated two-dimensional network of cytoskeletal actin filaments to illustrate that a pillar substrate is generally not a force sensor but a force-gradient sensor. In homogeneous networks the forces acting along the filaments can be approximated by analyzing only pillar deflections in the edge zones of the substrate and by integration over the corresponding force gradients. [source] | |||||||||||||