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Ablation of cytoskeletal filaments and mitochondria in live cells using a femtosecond laser nanoscissor. 用飞秒激光纳米剪刀消融活细胞中的细胞骨架细丝和线粒体。
Pub Date : 2005-01-01 DOI: 10.3970/MCB.2005.002.017
N. Shen, D. Datta, C. Schaffer, P. Leduc, D. Ingber, E. Mazur
Analysis of cell regulation requires methods for perturbing molecular processes within living cells with spatial discrimination on the nanometer-scale. We present a technique for ablating molecular structures in living cells using low-repetition rate, low-energy femtosecond laser pulses. By tightly focusing these pulses beneath the cell membrane, we ablate cellular material inside the cell through nonlinear processes. We selectively removed sub-micrometer regions of the cytoskeleton and individual mitochondria without altering neighboring structures or compromising cell viability. This nanoscissor technique enables non-invasive manipulation of the structural machinery of living cells with several-hundred-nanometer resolution. Using this approach, we unequivocally demonstrate that mitochondria are structurally independent functional units, and do not form a continuous network as suggested by some past studies.
细胞调控的分析需要在纳米尺度上对活细胞内的分子过程进行空间分辨的扰动方法。我们提出了一种利用低重复率、低能量飞秒激光脉冲消融活细胞分子结构的技术。通过将这些脉冲紧密聚焦在细胞膜下,我们通过非线性过程烧蚀细胞内的细胞物质。我们选择性地去除细胞骨架和单个线粒体的亚微米区域,而不改变邻近结构或损害细胞活力。这种纳米剪刀技术能够以几百纳米的分辨率对活细胞的结构机械进行非侵入性操作。使用这种方法,我们明确地证明了线粒体是结构上独立的功能单位,并没有像过去的一些研究表明的那样形成连续的网络。
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引用次数: 143
Shear force at the cell-matrix interface: enhanced analysis for microfabricated post array detectors. 细胞-基质界面的剪切力:微制造柱阵列探测器的增强分析。
Christopher A Lemmon, Nathan J Sniadecki, Sami Alom Ruiz, John L Tan, Lewis H Romer, Christopher S Chen

The interplay of mechanical forces between the extracellular environment and the cytoskeleton drives development, repair, and senescence in many tissues. Quantitative definition of these forces is a vital step in understanding cellular mechanosensing. Microfabricated post array detectors (mPADs) provide direct measurements of cell-generated forces during cell adhesion to extracellular matrix. A new approach to mPAD post labeling, volumetric imaging, and an analysis of post bending mechanics determined that cells apply shear forces and not point moments at the matrix interface. In addition, these forces could be accurately resolved from post deflections by using images of post tops and bases. Image analysis tools were then developed to increase the precision and throughput of post centroid location. These studies resulted in an improved method of force measurement with broad applicability and concise execution using a fully automated force analysis system. The new method measures cell-generated forces with less than 5% error and less than 90 seconds of computational time. Using this approach, we demonstrated direct and distinct relationships between cellular traction force and spread cell surface area for fibroblasts, endothelial cells, epithelial cells and smooth muscle cells.

细胞外环境和细胞骨架之间的机械力的相互作用驱动着许多组织的发育、修复和衰老。这些力的定量定义是理解细胞力学传感的重要一步。微加工后阵列探测器(mPADs)提供了细胞产生的力在细胞粘附到细胞外基质的直接测量。一种新的mPAD后标记、体积成像和后弯曲力学分析方法确定了细胞在基质界面施加剪切力而不是点矩。此外,利用柱顶和柱底的图像可以准确地从柱的偏转中分辨出这些力。然后开发了图像分析工具,以提高后质心定位的精度和吞吐量。这些研究产生了一种改进的力测量方法,使用全自动力分析系统,具有广泛的适用性和简洁的执行。新方法测量细胞产生的力,误差小于5%,计算时间小于90秒。利用这种方法,我们证明了成纤维细胞、内皮细胞、上皮细胞和平滑肌细胞的细胞牵引力与扩散细胞表面积之间存在直接而独特的关系。
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引用次数: 0
Growth, anisotropy, and residual stresses in arteries. 动脉的生长、各向异性和残余应力。
Pub Date : 2005-01-01 DOI: 10.3970/MCB.2005.002.027
K. Volokh, Y. Lev
A simple phenomenological theory of tissue growth is used in order to demonstrate that volumetric growth combined with material anisotropy can lead to accumulation of residual stresses in arteries. The theory is applied to growth of a cylindrical blood vessel with the anisotropy moduli derived from experiments. It is shown that bending resultants are developed in the ring cross-section of the artery. These resultants may cause the ring opening or closing after cutting the artery in vitro as it is observed in experiments. It is emphasized that the mode of the arterial ring opening is affected by the parameters of anisotropy.
组织生长的一个简单的现象学理论是为了证明体积增长结合材料各向异性可以导致残余应力在动脉的积累。利用实验得到的各向异性模量,将该理论应用于圆柱形血管的生长。结果表明,在动脉的环形截面上存在弯曲产物。这些结果可能导致环在体外切割动脉后打开或关闭,正如实验中观察到的那样。强调了各向异性参数对动脉环开口模式的影响。
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引用次数: 11
Ablation of cytoskeletal filaments and mitochondria in live cells using a femtosecond laser nanoscissor. 用飞秒激光纳米剪刀消融活细胞中的细胞骨架细丝和线粒体。
Nan Shen, Dabajyoti Datta, Chris B Schaffer, Philip LeDuc, Donald E Ingber, Eric Mazur

Analysis of cell regulation requires methods for perturbing molecular processes within living cells with spatial discrimination on the nanometer-scale. We present a technique for ablating molecular structures in living cells using low-repetition rate, low-energy femtosecond laser pulses. By tightly focusing these pulses beneath the cell membrane, we ablate cellular material inside the cell through nonlinear processes. We selectively removed sub-micrometer regions of the cytoskeleton and individual mitochondria without altering neighboring structures or compromising cell viability. This nanoscissor technique enables non-invasive manipulation of the structural machinery of living cells with several-hundred-nanometer resolution. Using this approach, we unequivocally demonstrate that mitochondria are structurally independent functional units, and do not form a continuous network as suggested by some past studies.

细胞调控的分析需要在纳米尺度上对活细胞内的分子过程进行空间分辨的扰动方法。我们提出了一种利用低重复率、低能量飞秒激光脉冲消融活细胞分子结构的技术。通过将这些脉冲紧密聚焦在细胞膜下,我们通过非线性过程烧蚀细胞内的细胞物质。我们选择性地去除细胞骨架和单个线粒体的亚微米区域,而不改变邻近结构或损害细胞活力。这种纳米剪刀技术能够以几百纳米的分辨率对活细胞的结构机械进行非侵入性操作。使用这种方法,我们明确地证明了线粒体是结构上独立的功能单位,并没有像过去的一些研究表明的那样形成连续的网络。
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引用次数: 0
The effect of longitudinal pre-stretch and radial constraint on the stress distribution in the vessel wall: a new hypothesis. 纵向预拉伸和径向约束对血管壁应力分布的影响:一个新的假设。
Pub Date : 2005-01-01 DOI: 10.3970/MCB.2005.002.041
Wei Zhang, Carly Herrera, S. Atluri, G. Kassab
It is well known that blood vessels shorten axially when excised. This is due to the perivascular tethering constraint by side branches and the existence of pre-stretch of blood vessels at the in situ state. Furthermore, vessels are radially constrained to various extents by the surrounding tissues at physiological loading. Our hypothesis is that the axial pre-stretch and radial constraint by the surrounding tissue homogenizes the stress and strain distributions in the vessel wall. A finite element analysis of porcine coronary artery and rabbit thoracic aorta based on measured material properties, geometry, residual strain and physiological loading is used to compute the intramural stresses and strains. We systematically examined the effect of pre-stretch and external radial constraint in both vessels. Our results show that both stretching in the axial direction and compression in the radial direction lead to a more homogeneous strain and stress state in the blood vessel wall. A "uniform biaxial strain" hypothesis is proposed for the blood vessel wall and the ramifications are discussed.
众所周知,切除血管后,血管轴向缩短。这是由于侧支的血管周围栓系约束和原位状态下血管预拉伸的存在。此外,在生理负荷下,血管在不同程度上受到周围组织的径向约束。我们的假设是,周围组织的轴向预拉伸和径向约束使血管壁的应力和应变分布均匀化。基于测量的材料性能、几何形状、残余应变和生理载荷,对猪冠状动脉和兔胸主动脉进行有限元分析,计算其内部应力和应变。我们系统地检查了预拉伸和外部径向约束对两种血管的影响。我们的研究结果表明,无论是轴向拉伸还是径向压缩,都会导致血管壁的应变和应力状态更加均匀。提出了血管壁的“均匀双轴应变”假设,并讨论了其后果。
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引用次数: 37
The effect of longitudinal pre-stretch and radial constraint on the stress distribution in the vessel wall: a new hypothesis. 纵向预拉伸和径向约束对血管壁应力分布的影响:一个新的假设。
Wei Zhang, Carly Herrera, Satya N Atluri, Ghassan S Kassab

It is well known that blood vessels shorten axially when excised. This is due to the perivascular tethering constraint by side branches and the existence of pre-stretch of blood vessels at the in situ state. Furthermore, vessels are radially constrained to various extents by the surrounding tissues at physiological loading. Our hypothesis is that the axial pre-stretch and radial constraint by the surrounding tissue homogenizes the stress and strain distributions in the vessel wall. A finite element analysis of porcine coronary artery and rabbit thoracic aorta based on measured material properties, geometry, residual strain and physiological loading is used to compute the intramural stresses and strains. We systematically examined the effect of pre-stretch and external radial constraint in both vessels. Our results show that both stretching in the axial direction and compression in the radial direction lead to a more homogeneous strain and stress state in the blood vessel wall. A "uniform biaxial strain" hypothesis is proposed for the blood vessel wall and the ramifications are discussed.

众所周知,切除血管后,血管轴向缩短。这是由于侧支的血管周围栓系约束和原位状态下血管预拉伸的存在。此外,在生理负荷下,血管在不同程度上受到周围组织的径向约束。我们的假设是,周围组织的轴向预拉伸和径向约束使血管壁的应力和应变分布均匀化。基于测量的材料性能、几何形状、残余应变和生理载荷,对猪冠状动脉和兔胸主动脉进行有限元分析,计算其内部应力和应变。我们系统地检查了预拉伸和外部径向约束对两种血管的影响。我们的研究结果表明,无论是轴向拉伸还是径向压缩,都会导致血管壁的应变和应力状态更加均匀。提出了血管壁的“均匀双轴应变”假设,并讨论了其后果。
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引用次数: 0
Endothelial cells as mechanical transducers: enzymatic activity and network formation under cyclic strain. 内皮细胞作为机械换能器:循环应变下的酶活性和网络形成。
Pub Date : 2004-12-01 DOI: 10.3970/MCB.2004.001.279
A. Shukla, A. R. Dunn, M. Moses, K. Vliet
Although it is established that endothelial cells can respond to external mechanical cues (e.g., alignment in the direction of fluid shear stress), the extent to which mechanical stress and strain applied via the endothelial cell substrate impact biomolecular and cellular processes is not well-understood. This issue is particularly important in the context of inflammation, vascular remodeling, and cancer progression, as each of these processes occurs concurrently with localized increases in strain and marked changes in molecules secreted by adjacent cells. Here, we systematically vary the level and duration of cyclic tensile strain applied to human dermal microvascular and bovine capillary endothelial cells via substrate deflection, and then correlate these cues with the secretion of extracellular matrix-degrading enzymes and a morphological transition from confluent monolayers to well-defined multicellular networks that resemble capillary tube-like structures. For a constant chemical environment, we find that super-physiological mechanical strain stimulates both endothelial cell secretion of latent matrix metalloprotease-2 and multicellular networks in a time- and strain-dependent manner. These results demonstrate coupling between the mechanical and biochemical states of microvascular endothelial cells, and indicate that elevated local stress may directly impact new capillary growth (angiogenesis) toward growing tumors and at capillary wall defect sites.
虽然内皮细胞可以响应外部机械信号(例如,流体剪切应力方向的对齐),但通过内皮细胞底物施加的机械应力和应变对生物分子和细胞过程的影响程度尚不清楚。这个问题在炎症、血管重塑和癌症进展的背景下尤为重要,因为这些过程中的每一个都伴随着局部应变的增加和邻近细胞分泌的分子的显著变化。在这里,我们系统地改变了通过底物挠曲作用于人皮肤微血管和牛毛细血管内皮细胞的循环拉伸应变的水平和持续时间,然后将这些线索与细胞外基质降解酶的分泌和从融合单层到类似毛细血管样结构的明确的多细胞网络的形态转变联系起来。对于恒定的化学环境,我们发现超生理机械应变以时间和应变依赖的方式刺激内皮细胞分泌潜伏基质金属蛋白酶-2和多细胞网络。这些结果证明了微血管内皮细胞的机械和生化状态之间的耦合,并表明局部应激升高可能直接影响肿瘤生长和毛细血管壁缺陷部位的新毛细血管生长(血管生成)。
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引用次数: 21
Forces required to initiate membrane tether extrusion from cell surface depend on cell type but not on the surface molecule. 从细胞表面启动膜系索挤压所需的力取决于细胞类型,而不取决于表面分子。
Pub Date : 2004-12-01 DOI: 10.3970/MCB.2004.001.245
W. Marcus, R. McEver, C. Zhu
When a cell adhered to another cell or substratum via surface proteins is forced to detach, lipid membrane tethers are often extruded from the cell surface before the protein bond dissociates. For example, during the inflammatory reaction leukocytes roll on the surface of activated endothelial cells. The rolling adhesion is mediated by interactions of selectins with their ligands, e.g., P-selectin glycoprotein ligand (PSGL)-1, which extrudes membrane tethers from the surfaces of both leukocytes and endothelial cells. Membrane tether extrusion has been suggested to regulate leukocyte rolling. Here we examine several factors that may affect forces required to initiate membrane tethers, or initial tether force. It was found that initial tether forces were similar regardless of the presence or absence of the cytoplasmic tail of P-selectin and regardless of whether the tethers were extruded via binding to PSGL-1 or Fcy receptors. Initial tether forces were found to depend on the cell types tested and were greatly reduced by treatment of latrunculin A, which inhibits actin polymerization. These data provide additional insights to the control of membrane tether extrusion, which should be taken into account when cellular functions such as rolling where tether extrusion plays a regulatory role are compared using different cell types expressing the same molecule.
当一个细胞通过表面蛋白质粘附到另一个细胞或基质上时,脂质膜系链通常在蛋白质键解离之前从细胞表面挤出。例如,在炎症反应中,白细胞在活化的内皮细胞表面滚动。滚动粘附是由选择素与其配体的相互作用介导的,例如p -选择素糖蛋白配体(PSGL)-1,其从白细胞和内皮细胞表面挤出膜系链。膜系索挤压被认为可以调节白细胞的滚动。在这里,我们研究了几个可能影响启动膜系索或初始系索力所需的力的因素。研究发现,无论p -选择素的细胞质尾部是否存在,也无论系索是通过与PSGL-1或Fcy受体结合而挤出的,初始系索力都是相似的。发现初始系绳力取决于所测试的细胞类型,并通过抑制肌动蛋白聚合的latrunculin A处理大大降低。这些数据为控制膜系绳挤压提供了额外的见解,当使用表达相同分子的不同细胞类型比较细胞功能(如滚动)时,应该考虑到系绳挤压发挥调节作用。
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引用次数: 12
Force-induced unfolding of the focal adhesion targeting domain and the influence of paxillin binding. 力诱导的黏附靶区展开和paxillin结合的影响。
Pub Date : 2004-12-01 DOI: 10.3970/MCB.2004.001.253
M. R. K. Mofrad, J. Golji, N. A. A. Rahim, R. Kamm
Membrane-bound integrin receptors are linked to intracellular signaling pathways through focal adhesion kinase (FAK). FAK tends to colocalize with integrin receptors at focal adhesions through its C-terminal focal adhesion targeting (FAT) domain. Through recruitment and binding of intracellular proteins, FAs transduce signals between the intracellular and extracellular regions that regulate a variety of cellular processes including cell migration, proliferation, apoptosis and detachment from the ECM. The mechanism of signaling through the cell is of interest, especially the transmission of mechanical forces and subsequent transduction into biological signals. One hypothesis relates mechanotransduction to conformational changes in intracellular proteins in the force transmission pathway, connecting the extracellular matrix with the cytoskeleton through FAs. To assess this hypothesis, we performed steered molecular dynamics simulations to mechanically unfold FAT and monitor how force-induced changes in the molecular conformation of FAT affect its binding to paxillin.
膜结合整合素受体通过局灶黏附激酶(FAK)与细胞内信号通路相连。FAK倾向于通过其c端局灶黏附靶向(FAT)区域与整合素受体共定位。通过细胞内蛋白的募集和结合,FAs在细胞内和细胞外区域之间传递信号,调节多种细胞过程,包括细胞迁移、增殖、凋亡和脱离ECM。信号通过细胞的机制是感兴趣的,特别是机械力的传递和随后的转导为生物信号。一种假设将机械转导与力传递途径中细胞内蛋白质的构象变化联系起来,通过FAs将细胞外基质与细胞骨架连接起来。为了评估这一假设,我们进行了定向分子动力学模拟,以机械地展开FAT,并监测FAT分子构象的力诱导变化如何影响其与帕西林的结合。
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引用次数: 43
Forces required to initiate membrane tether extrusion from cell surface depend on cell type but not on the surface molecule. 从细胞表面启动膜系索挤压所需的力取决于细胞类型,而不取决于表面分子。
Warren D Marcus, Rodger P McEver, Cheng Zhu

When a cell adhered to another cell or substratum via surface proteins is forced to detach, lipid membrane tethers are often extruded from the cell surface before the protein bond dissociates. For example, during the inflammatory reaction leukocytes roll on the surface of activated endothelial cells. The rolling adhesion is mediated by interactions of selectins with their ligands, e.g., P-selectin glycoprotein ligand (PSGL)-1, which extrudes membrane tethers from the surfaces of both leukocytes and endothelial cells. Membrane tether extrusion has been suggested to regulate leukocyte rolling. Here we examine several factors that may affect forces required to initiate membrane tethers, or initial tether force. It was found that initial tether forces were similar regardless of the presence or absence of the cytoplasmic tail of P-selectin and regardless of whether the tethers were extruded via binding to PSGL-1 or Fcy receptors. Initial tether forces were found to depend on the cell types tested and were greatly reduced by treatment of latrunculin A, which inhibits actin polymerization. These data provide additional insights to the control of membrane tether extrusion, which should be taken into account when cellular functions such as rolling where tether extrusion plays a regulatory role are compared using different cell types expressing the same molecule.

当一个细胞通过表面蛋白质粘附到另一个细胞或基质上时,脂质膜系链通常在蛋白质键解离之前从细胞表面挤出。例如,在炎症反应中,白细胞在活化的内皮细胞表面滚动。滚动粘附是由选择素与其配体的相互作用介导的,例如p -选择素糖蛋白配体(PSGL)-1,其从白细胞和内皮细胞表面挤出膜系链。膜系索挤压被认为可以调节白细胞的滚动。在这里,我们研究了几个可能影响启动膜系索或初始系索力所需的力的因素。研究发现,无论p -选择素的细胞质尾部是否存在,也无论系索是通过与PSGL-1或Fcy受体结合而挤出的,初始系索力都是相似的。发现初始系绳力取决于所测试的细胞类型,并通过抑制肌动蛋白聚合的latrunculin A处理大大降低。这些数据为控制膜系绳挤压提供了额外的见解,当使用表达相同分子的不同细胞类型比较细胞功能(如滚动)时,应该考虑到系绳挤压发挥调节作用。
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引用次数: 0
期刊
Mechanics & chemistry of biosystems : MCB
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