Three‐dimensional reconstruction of aqueous channels in human trabecular meshwork using light microscopy and confocal microscopy

Camp, Jon J.; Hann, Cheryl R.; Johnson, Douglas H.; Tarara, James E.; Robb, Richard A.

doi:10.1002/sca.4950190402

Cited by 22 publications

(9 citation statements)

References 13 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…SABETRASEKH ET AL. [26], and also similar to that of Lin et al [27,28]. It first found voxels representing air that maintained connections to other air voxels and labeled regions of connected and isolated air with a connectedcomponents operation.…”

supporting

confidence: 51%

A Novel Ultra-porous Titanium Dioxide Ceramic with Excellent Biocompatibility

et al. 2010

View full text Add to dashboard Cite

The current study compares biocompatibility, cell growth and morphology, pore diameter distribution, and interconnectivity of a novel titanium dioxide (TiO(2)) bone graft substitute granules with three different commercially available bone graft granules Natix, Straumann BoneCeramic, and Bio-Oss. Human primary mesenchymal stem cells were cultured on the bone graft substitutes and cell viability and proliferation were evaluated after 1 and 3 days. The microstructural properties of the bone graft substitutes were evaluated by scanning electron microscopy, micro-computed tomography analysis, and mechanical testing. The cell viability and proliferation, porosity, interconnectivity, open pore size, and surface area-to-volume ratio of TiO(2) granules were significantly higher than commercial bone granules (Bio-Oss and Straumann BoneCeramic).

show abstract

supporting

confidence: 51%

A Novel Ultra-porous Titanium Dioxide Ceramic with Excellent Biocompatibility

et al. 2010

View full text Add to dashboard Cite

show abstract

“…The algorithm is based on a method by Camp and colleagues,20 and also similar to that of Lin and colleagues21 It first found voxels representing air that maintained connections to other air voxels and labeled regions of connected and isolated air with a connected‐components operation. It then performed a mathematical morphological operation known as opening ,22 which is a morphological erosion followed by a dilation of the air space in all three dimensions, essentially closing off small air connections.…”

Section: Interconnectivity Analysismentioning

confidence: 99%

Quantitative analysis of interconnectivity of porous biodegradable scaffolds with micro‐computed tomography

Moore

Jabbari

Ritman

et al. 2004

J Biomedical Materials Res

153

123

View full text Add to dashboard Cite

Pore interconnectivity within scaffolds is an important parameter influencing cell migration and tissue ingrowth needed to promote tissue regeneration. Methods for assessment of interconnectivity are usually qualitative, restricted to two-dimensional images, or are destructive. Microcomputed tomography nondestructively provides three-dimensional (3D) images of intact specimens at high spatial resolutions. We describe an image analysis technique for quantitative assessment of scaffold interconnectivity. Scaffolds were made via a particulate leaching process with 75%, 80%, 85%, and 88% volumetric porogen fractions. Specimens were scanned and resulting 3D, digital images were analyzed with a custom algorithm. A series of virtual, idealized scaffolds were also created for illustration of the algorithm's analysis approach and for its validation. The program calculated accessible void fractions over a range of minimum connection sizes. In real specimens, nearly 100% of the porous volume was connected with outside air for connections greater than or equal to 20 microm in their smallest dimension. In scaffolds made with 75% porogen, the accessible void fraction decreased to 78% if only those connections greater than or equal to 260 microm were considered. The relationship between accessible void fraction and connection size varied as a function of porogen content. The interconnectivity parameter described here may have implications for cell migration and tissue growth into scaffolds.

show abstract

“…Uneven brightness may also occur along the depth of reconstructed image volumes due to factors such as varying imaging conditions after each cycle of sectioning, inherent inconsistencies or heterogeneities in the sample and/or photo bleaching of the fluorophores because of pro‐longed exposure to laser. This can be rectified using histogram matching (Castleman, ; Camp et al ., ) that matches the histograms of successive image slices to that of the first image of the reconstructed image volume to give uniform intensity along the depth.…”

Section: Discussionmentioning

confidence: 99%

3D imaging of cement‐based materials at submicron resolution by combining laser scanning confocal microscopy with serial sectioning

Yio

Mac

Wong

et al. 2015

Journal of Microscopy

View full text Add to dashboard Cite

SummaryIn this paper, we present a new method to reconstruct large volumes of nontransparent porous materials at submicron resolution. The proposed method combines fluorescence laser scanning confocal microscopy with serial sectioning to produce a series of overlapping confocal z-stacks, which are then aligned and stitched based on phase correlation. The method can be extended in the XY plane to further increase the overall image volume. Resolution of the reconstructed image volume does not degrade with increase in sample size. We have used the method to image cementitious materials, hardened cement paste and concrete and the results obtained show that the method is reliable. Possible applications of the method such as three-dimensional characterization of the pores and microcracks in hardened concrete, three-dimensional particle shape characterization of cementitious materials and threedimensional characterization of other porous materials such as rocks and bioceramics are discussed.

show abstract

Three‐dimensional reconstruction of aqueous channels in human trabecular meshwork using light microscopy and confocal microscopy

Cited by 22 publications

References 13 publications

A Novel Ultra-porous Titanium Dioxide Ceramic with Excellent Biocompatibility

A Novel Ultra-porous Titanium Dioxide Ceramic with Excellent Biocompatibility

Quantitative analysis of interconnectivity of porous biodegradable scaffolds with micro‐computed tomography

3D imaging of cement‐based materials at submicron resolution by combining laser scanning confocal microscopy with serial sectioning

Contact Info

Product

Resources

About