Three-dimensional micro-scale strain mapping in living biological soft tissues.

Non-invasive characterization of the mechanical micro-environment surrounding cells in biological tissues at multiple length scales is important for the understanding of the role of mechanics in regulating the biosynthesis and phenotype of cells. However, there is a lack of imaging methods that allow for characterization of the cell micro-environment in three-dimensional (3D) space. The aims of this study were (i) to develop a multi-photon laser microscopy protocol capable of imprinting 3D grid lines onto living tissue at a high spatial resolution, and (ii) to develop image processing software capable of analyzing the resulting microscopic images and performing high resolution 3D strain analyses. Using articular cartilage as the biological tissue of interest, we present a novel two-photon excitation imaging technique for measuring the internal 3D kinematics in intact cartilage at sub-micrometer resolution, spanning length scales from the tissue to the cell level. Using custom image processing software, we provide accurate and robust 3D micro-strain analysis that allows for detailed qualitative and quantitative assessment of the 3D tissue kinematics. This novel technique preserves tissue structural integrity post-scanning, therefore allowing for multiple strain measurements at different time points in the same specimen. The proposed technique is versatile and opens doors for experimental and theoretical investigations on the relationship between tissue deformation and cell biosynthesis. Studies of this nature may enhance our understanding of the mechanisms underlying cell mechano-transduction, and thus, adaptation and degeneration of soft connective tissues. STATEMENT OF SIGNIFICANCE We presented a novel two-photon excitation imaging technique for measuring the internal 3D kinematics in intact cartilage at sub-micrometer resolution, spanning from tissue length scale to cellular length scale. Using a custom image processing software (lsmgridtrack), we provide accurate and robust micro-strain analysis that allowed for detailed qualitative and quantitative assessment of the 3D tissue kinematics. The approach presented here can also be applied to other biological tissues such as meniscus and annulus fibrosus, as well as tissue-engineered tissues for the characterization of their mechanical properties. This imaging technique opens doors for experimental and theoretical investigation on the relationship between tissue deformation and cell biosynthesis. Studies of this nature may enhance our understanding of the mechanisms underlying cell mechano-transduction, and thus, adaptation and degeneration of soft connective tissues.

[1]  F. Guilak,et al.  Transfer of macroscale tissue strain to microscale cell regions in the deformed meniscus. , 2008, Biophysical journal.

[2]  M. Hull,et al.  Heterogeneous three‐dimensional strain fields during unconfined cyclic compression in bovine articular cartilage explants , 2005, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[3]  W. Denk,et al.  Two-photon laser scanning fluorescence microscopy. , 1990, Science.

[4]  Mark R. Buckley,et al.  High-resolution spatial mapping of shear properties in cartilage. , 2010, Journal of biomechanics.

[5]  Gerhard A Holzapfel,et al.  Modelling non-symmetric collagen fibre dispersion in arterial walls , 2015, Journal of The Royal Society Interface.

[6]  Albert C. Chen,et al.  Depth‐dependent confined compression modulus of full‐thickness bovine articular cartilage , 1997, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[7]  W. Herzog,et al.  Unfolding of membrane ruffles of in situ chondrocytes under compressive loads , 2017, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[8]  Farshid Guilak,et al.  Zonal changes in the three-dimensional morphology of the chondron under compression: the relationship among cellular, pericellular, and extracellular deformation in articular cartilage. , 2007, Journal of biomechanics.

[9]  Won C Bae,et al.  Biomechanics of cartilage articulation: effects of lubrication and degeneration on shear deformation. , 2008, Arthritis and rheumatism.

[10]  Walter Herzog,et al.  Mechanical loading of in situ chondrocytes in lapine retropatellar cartilage after anterior cruciate ligament transection , 2010, Journal of The Royal Society Interface.

[11]  T Christian Gasser,et al.  Nonlinear elasticity of biological tissues with statistical fibre orientation , 2010, Journal of The Royal Society Interface.

[12]  Farshid Guilak,et al.  Site-Specific Molecular Diffusion in Articular Cartilage Measured using Fluorescence Recovery after Photobleaching , 2003, Annals of Biomedical Engineering.

[13]  W. Herzog,et al.  Chondrocyte deformation under extreme tissue strain in two regions of the rabbit knee joint. , 2013, Journal of biomechanics.

[14]  W. Denk,et al.  Two-photon imaging to a depth of 1000 microm in living brains by use of a Ti:Al2O3 regenerative amplifier. , 2003, Optics letters.

[15]  Stephen J. Wright,et al.  Numerical Optimization , 2018, Fundamental Statistical Inference.

[16]  Itai Cohen,et al.  Measuring microscale strain fields in articular cartilage during rapid impact reveals thresholds for chondrocyte death and a protective role for the superficial layer. , 2015, Journal of biomechanics.

[17]  John D. Hunter,et al.  Matplotlib: A 2D Graphics Environment , 2007, Computing in Science & Engineering.

[18]  D. Elliott,et al.  DTAF Dye Concentrations Commonly Used to Measure Microscale Deformations in Biological Tissues Alter Tissue Mechanics , 2014, PloS one.

[19]  Itai Cohen,et al.  Multiscale Strain as a Predictor of Impact-Induced Fissuring in Articular Cartilage. , 2017, Journal of biomechanical engineering.

[20]  N. A. Abu Osman,et al.  The properties of chondrocyte membrane reservoirs and their role in impact-induced cell death. , 2013, Biophysical journal.

[21]  T. B. Kirk,et al.  Confocal laser scanning microscopy in orthopaedic research. , 2005, Progress in histochemistry and cytochemistry.

[22]  Donald E. Ingber,et al.  Mechanosensitive mechanisms in transcriptional regulation , 2012, Journal of Cell Science.

[23]  Stockwell Ra The interrelationship of cell density and cartilage thickness in mammalian articular cartilage. , 1971 .

[24]  Gaël Varoquaux,et al.  The NumPy Array: A Structure for Efficient Numerical Computation , 2011, Computing in Science & Engineering.

[25]  Gerard A Ateshian,et al.  Modeling the matrix of articular cartilage using a continuous fiber angular distribution predicts many observed phenomena. , 2009, Journal of biomechanical engineering.

[26]  W M Lai,et al.  Fluid transport and mechanical properties of articular cartilage: a review. , 1984, Journal of biomechanics.

[27]  C. Giverso,et al.  Non-linear model for compression tests on articular cartilage. , 2015, Journal of Biomechanical Engineering.

[28]  Dawn M Elliott,et al.  Macro- to microscale strain transfer in fibrous tissues is heterogeneous and tissue-specific. , 2013, Biophysical journal.

[29]  G. Ateshian,et al.  Two-dimensional strain fields on the cross-section of the human patellofemoral joint under physiological loading. , 2009, Journal of biomechanics.

[30]  W. Webb,et al.  Nonlinear magic: multiphoton microscopy in the biosciences , 2003, Nature Biotechnology.

[31]  Frederick Sachs,et al.  Synergy between Piezo1 and Piezo2 channels confers high-strain mechanosensitivity to articular cartilage , 2014, Proceedings of the National Academy of Sciences.

[32]  Noor Azuan Abu Osman,et al.  Dual photon excitation microscopy and image threshold segmentation in live cell imaging during compression testing. , 2013, Journal of biomechanics.

[33]  S. Bruehlmann,et al.  ISSLS Prize Winner: Collagen Fibril Sliding Governs Cell Mechanics in the Anulus Fibrosus: An In Situ Confocal Microscopy Study of Bovine Discs , 2004, Spine.

[34]  Walter Herzog,et al.  Confocal microscopy indentation system for studying in situ chondrocyte mechanics. , 2009, Medical engineering & physics.

[35]  V. Mow,et al.  Chondrocyte deformation and local tissue strain in articular cartilage: A confocal microscopy study , 1995, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[36]  W. Herzog,et al.  Mechanical behaviour of in-situ chondrocytes subjected to different loading rates: a finite element study , 2012, Biomechanics and Modeling in Mechanobiology.

[37]  D. Elliott,et al.  Interfibrillar shear stress is the loading mechanism of collagen fibrils in tendon. , 2014, Acta biomaterialia.

[38]  Scott C. Sibole,et al.  Extracellular matrix integrity affects the mechanical behaviour of in-situ chondrocytes under compression. , 2014, Journal of biomechanics.

[39]  Luis Ibáñez,et al.  The Design of SimpleITK , 2013, Front. Neuroinform..

[40]  Alfio Grillo,et al.  Elasticity and permeability of porous fibre-reinforced materials under large deformations , 2012 .