Literature DB >> 19772536

Three-dimensional surface texture visualization of bone tissue through epifluorescence-based serial block face imaging.

C R Slyfield1, K E Niemeyer, E V Tkachenko, R E Tomlinson, G G Steyer, C G Patthanacharoenphon, G J Kazakia, D L Wilson, C J Hernandez.   

Abstract

Serial block face imaging is a microscopy technique in which the top of a specimen is cut or ground away and a mosaic of images is collected of the newly revealed cross-section. Images collected from each slice are then digitally stacked to achieve 3D images. The development of fully automated image acquisition devices has made serial block face imaging more attractive by greatly reducing labour requirements. The technique is particularly attractive for studies of biological activity within cancellous bone as it has the capability of achieving direct, automated measures of biological and morphological traits and their associations with one another. When used with fluorescence microscopy, serial block face imaging has the potential to achieve 3D images of tissue as well as fluorescent markers of biological activity. Epifluorescence-based serial block face imaging presents a number of unique challenges for visualizing bone specimens due to noise generated by sub-surface signal and local variations in tissue autofluorescence. Here we present techniques for processing serial block face images of trabecular bone using a combination of non-uniform illumination correction, precise tiling of the mosaic in each cross-section, cross-section alignment for vertical stacking, removal of sub-surface signal and segmentation. The resulting techniques allow examination of bone surface texture that will enable 3D quantitative measures of biological processes in cancellous bone biopsies.

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Year:  2009        PMID: 19772536      PMCID: PMC2978811          DOI: 10.1111/j.1365-2818.2009.03204.x

Source DB:  PubMed          Journal:  J Microsc        ISSN: 0022-2720            Impact factor:   1.758


  17 in total

1.  Combined inter-observer and inter-method variation in bone histomorphometry.

Authors:  C D Wright; S Vedi; N J Garrahan; M Stanton; S W Duffy; J E Compston
Journal:  Bone       Date:  1992       Impact factor: 4.398

2.  Automated microscopy system for mosaic acquisition and processing.

Authors:  S K Chow; H Hakozaki; D L Price; N A B MacLean; T J Deerinck; J C Bouwer; M E Martone; S T Peltier; M H Ellisman
Journal:  J Microsc       Date:  2006-05       Impact factor: 1.758

3.  Stress-concentrating effect of resorption lacunae in trabecular bone.

Authors:  L M McNamara; J C Van der Linden; H Weinans; P J Prendergast
Journal:  J Biomech       Date:  2006       Impact factor: 2.712

4.  Automated high-resolution three-dimensional fluorescence imaging of large biological specimens.

Authors:  G J Kazakia; J J Lee; M Singh; R F Bigley; R B Martin; T M Keaveny
Journal:  J Microsc       Date:  2007-02       Impact factor: 1.758

5.  Assessment of bone tissue mineralization by conventional x-ray microcomputed tomography: comparison with synchrotron radiation microcomputed tomography and ash measurements.

Authors:  G J Kazakia; A J Burghardt; S Cheung; S Majumdar
Journal:  Med Phys       Date:  2008-07       Impact factor: 4.071

6.  Inter-observer and intra-observer variation in bone histomorphometry.

Authors:  J E Compston; S Vedi; A J Stellon
Journal:  Calcif Tissue Int       Date:  1986-02       Impact factor: 4.333

7.  Unbiased stereological estimation of osteoid and resorption fractional surfaces in trabecular bone using vertical sections: sampling efficiency and biological variation.

Authors:  A Vesterby; H J Gundersen; F Melsen
Journal:  Bone       Date:  1987       Impact factor: 4.398

8.  Bone histomorphometry: standardization of nomenclature, symbols, and units. Report of the ASBMR Histomorphometry Nomenclature Committee.

Authors:  A M Parfitt; M K Drezner; F H Glorieux; J A Kanis; H Malluche; P J Meunier; S M Ott; R R Recker
Journal:  J Bone Miner Res       Date:  1987-12       Impact factor: 6.741

9.  Consequences of the remodelling process for vertebral trabecular bone structure: a scanning electron microscopy study (uncoupling of unloaded structures).

Authors:  L Mosekilde
Journal:  Bone Miner       Date:  1990-07

10.  Estrogen and "exercise" have a synergistic effect in preventing bone loss in the lumbar vertebra and femoral neck of the ovariectomized rat.

Authors:  C Y Li; W S S Jee; J L Chen; A Mo; R B Setterberg; M Su; X Y Tian; Y F Ling; W Yao
Journal:  Calcif Tissue Int       Date:  2002-10-10       Impact factor: 4.333
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  16 in total

1.  Deciphering the elusive nature of sharp bone trauma using epifluorescence macroscopy: a comparison study multiplexing classical imaging approaches.

Authors:  Caroline Capuani; Jacques Rouquette; Bruno Payré; Jacques Moscovici; Marie Bernadette Delisle; Norbert Telmon; Céline Guilbeau-Frugier
Journal:  Int J Legal Med       Date:  2012-02-23       Impact factor: 2.686

Review 2.  Multiscale imaging of bone microdamage.

Authors:  Atharva A Poundarik; Deepak Vashishth
Journal:  Connect Tissue Res       Date:  2015-02-09       Impact factor: 3.417

3.  Mechanical failure begins preferentially near resorption cavities in human vertebral cancellous bone under compression.

Authors:  C R Slyfield; E V Tkachenko; S E Fischer; K M Ehlert; I H Yi; M G Jekir; R G O'Brien; T M Keaveny; C J Hernandez
Journal:  Bone       Date:  2012-03-09       Impact factor: 4.398

4.  Multimodal optical microscopy methods reveal polyp tissue morphology and structure in Caribbean reef building corals.

Authors:  Mayandi Sivaguru; Glenn A Fried; Carly A H Miller; Bruce W Fouke
Journal:  J Vis Exp       Date:  2014-09-05       Impact factor: 1.355

5.  Material heterogeneity in cancellous bone promotes deformation recovery after mechanical failure.

Authors:  Ashley M Torres; Jonathan B Matheny; Tony M Keaveny; David Taylor; Clare M Rimnac; Christopher J Hernandez
Journal:  Proc Natl Acad Sci U S A       Date:  2016-02-29       Impact factor: 11.205

6.  Minimizing Interpolation Bias and Precision Error in In Vivo µCT-Based Measurements of Bone Structure and Dynamics.

Authors:  Chantal M J de Bakker; Allison R Altman; Connie Li; Mary Beth Tribble; Carina Lott; Wei-Ju Tseng; X Sherry Liu
Journal:  Ann Biomed Eng       Date:  2016-01-19       Impact factor: 3.934

7.  Three-dimensional characterization of resorption cavity size and location in human vertebral trabecular bone.

Authors:  M G Goff; C R Slyfield; S R Kummari; E V Tkachenko; S E Fischer; Y H Yi; M G Jekir; T M Keaveny; C J Hernandez
Journal:  Bone       Date:  2012-04-03       Impact factor: 4.398

8.  Analysis of the effect of osteon diameter on the potential relationship of osteocyte lacuna density and osteon wall thickness.

Authors:  John G Skedros; Gunnar C Clark; Scott M Sorenson; Kevin W Taylor; Shijing Qiu
Journal:  Anat Rec (Hoboken)       Date:  2011-08-01       Impact factor: 2.064

9.  The effects of tensile-compressive loading mode and microarchitecture on microdamage in human vertebral cancellous bone.

Authors:  Floor M Lambers; Amanda R Bouman; Evgeniy V Tkachenko; Tony M Keaveny; Christopher J Hernandez
Journal:  J Biomech       Date:  2014-11-28       Impact factor: 2.712

10.  μCT-based, in vivo dynamic bone histomorphometry allows 3D evaluation of the early responses of bone resorption and formation to PTH and alendronate combination therapy.

Authors:  Chantal M J de Bakker; Allison R Altman; Wei-Ju Tseng; Mary Beth Tribble; Connie Li; Abhishek Chandra; Ling Qin; X Sherry Liu
Journal:  Bone       Date:  2014-12-30       Impact factor: 4.398
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