Väinö Mikael Mäntylä, Arttu Juhani Lehtonen, Vesa Korhonen, Linda Srbova, Juho Pokki
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引用次数: 0
摘要
X 射线被广泛用于乳房 X 射线照相术和乳腺癌的放射治疗。研究的重点是 X 射线对乳腺组织细胞的影响,而不是对组织的非生命物质--细胞外基质的影响。目前还不清楚 X 射线辐照对基质机械线索的影响,而已知机械线索可调节恶性癌细胞的行为。在这里,我们开发了一种基于磁微流变学的技术,可以量化 X 射线辐照对基质粘弹性或(类固态)弹性和(类液态)粘性特征的影响。为了建立乳腺组织细胞外基质模型,我们使用了组织基质的主要成分--1 型胶原蛋白。我们使用直径为 10 微米的磁性探针来测量胶原蛋白基质。在每个基质中,利用微回辐射计控制的磁力对探针进行纳米操纵,同时检测探针的位移,以测量粘弹性。胶原蛋白基质的数据与粘弹性的典型空间变化有关。我们发现,较高的辐照剂量(320 Gy)会使胶原蛋白基质局部软化,并增加其损失正切,这表明胶原蛋白基质具有较高的液态性质。而对于较低的临床相关辐照剂量(55 Gy),我们发现基质的粘弹性变化并不明显。我们提供了这种与辐照相关的技术,用于检测和改变细胞大小尺度的基质粘弹性线索。该技术可加强对各种乳腺癌放疗类型中辐照组织成分的表征。
Quantifying the Influence of X-Ray Irradiation on Cell-Size-Scale Viscoelasticity of Collagen Type 1.
X-rays are widely used in mammography and radiotherapy of breast cancer. The research has focused on the effects of X-rays on cells in breast tissues, instead of the tissues' nonliving material, extracellular matrix. It is unclear what the influence of X-ray irradiation is on the matrix's mechanical cues, known to regulate malignant cancer-cell behaviors. Here, we developed a technique based on magnetic microrheology that can quantify the influence of X-ray irradiation on matrix viscoelasticity--or (solid-like) elastic and (liquid-like) viscous characteristics--at cell-size scales. To model breast-tissue extracellular matrix, we used the primary component of the tissue matrix, collagen type 1, as it is for control, and as irradiated by X-rays (tube voltage 50 kV). We used a magnetic microrheometer to measure collagen matrices using 10-μm-diameter magnetic probes. In each matrix, the probes were nanomanipulated using controlled magnetic forces by the microrheometer while the probes' displacements were detected to measure the viscoelasticity. The collagen-matrix data involve with a typical spatial variation in viscoelasticity. We find that higher irradiation doses (320 Gy) locally reduce stiffness (soften) collagen matrices and increase their loss tangent, indicating an elevated liquid-like nature. For lower, clinically relevant irradiation doses (54 Gy), we find insignificant matrix-viscoelasticity changes. We provide this irradiation-related technique for detection, and modification, of matrix viscoelastic cues at cell-size scales. The technique enables enhanced characterization of irradiated tissue constituents in a variety of breast-cancer radiotherapy types.
期刊介绍:
Artificial Organs and Prostheses; Bioinstrumentation and Measurements; Bioheat Transfer; Biomaterials; Biomechanics; Bioprocess Engineering; Cellular Mechanics; Design and Control of Biological Systems; Physiological Systems.