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custom dewarping program (MathWorks Inc)

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MathWorks Inc custom dewarping program
Schematic of workflow for 3D image reconstruction, illustrating (A) confocal image tiles, (B) stitched confocal z -stacks, (C) confocal z -stacks cropped to the same x and y dimensions, (D) stacked confocal z-stacks, and (E) the final 3D volume after <t>dewarping,</t> intensity normalization, and alignment.

Schematic of workflow for 3D image reconstruction, illustrating (A) confocal image tiles, (B) stitched confocal z -stacks, (C) confocal z -stacks cropped to the same x and y dimensions, (D) stacked confocal z-stacks, and (E) the final 3D volume after <t>dewarping,</t> intensity normalization, and alignment.

Custom Dewarping Program, supplied by MathWorks Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/custom dewarping program/product/MathWorks Inc
Average 90 stars, based on 1 article reviews

custom dewarping program - by Bioz Stars, 2026-04

90/100 stars

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1) Product Images from "3D Reconstruction of the Intracortical Volume Around a Hybrid Microelectrode Array"

Article Title: 3D Reconstruction of the Intracortical Volume Around a Hybrid Microelectrode Array

Journal: Frontiers in Neuroscience

doi: 10.3389/fnins.2019.00393

Figure Legend Snippet: Schematic of workflow for 3D image reconstruction, illustrating (A) confocal image tiles, (B) stitched confocal z -stacks, (C) confocal z -stacks cropped to the same x and y dimensions, (D) stacked confocal z-stacks, and (E) the final 3D volume after dewarping, intensity normalization, and alignment.

Techniques Used:

(A) 3D volume rendering of GFAP (green) and NeuN (magenta) after stitching, cropping, and stacking. Dewarping, alignment, and intensity normalization have not yet been performed. (B) Vertical cross section through the 3D volume. The dark bands are dark, out-of-focus optical slices above and below the actual tissue in each section.

Figure Legend Snippet: (A) 3D volume rendering of GFAP (green) and NeuN (magenta) after stitching, cropping, and stacking. Dewarping, alignment, and intensity normalization have not yet been performed. (B) Vertical cross section through the 3D volume. The dark bands are dark, out-of-focus optical slices above and below the actual tissue in each section.

Techniques Used:

(A) Schematic of the dewarping algorithm. The brightest contiguous subset of voxels in z is retained while the rest are discarded, resulting in a flatter section. (B) Vertical cross section through a section before dewarping with height scaled 10×. The section is tilted, has a large wrinkle, and has a stitching artifact. (C) After dewarping the tissue is nearly flat (height still scaled 10×).

Figure Legend Snippet: (A) Schematic of the dewarping algorithm. The brightest contiguous subset of voxels in z is retained while the rest are discarded, resulting in a flatter section. (B) Vertical cross section through a section before dewarping with height scaled 10×. The section is tilted, has a large wrinkle, and has a stitching artifact. (C) After dewarping the tissue is nearly flat (height still scaled 10×).

Techniques Used:

Image Search Results

Journal: Frontiers in Neuroscience

Article Title: 3D Reconstruction of the Intracortical Volume Around a Hybrid Microelectrode Array

doi: 10.3389/fnins.2019.00393

Figure Lengend Snippet: Schematic of workflow for 3D image reconstruction, illustrating (A) confocal image tiles, (B) stitched confocal z -stacks, (C) confocal z -stacks cropped to the same x and y dimensions, (D) stacked confocal z-stacks, and (E) the final 3D volume after dewarping, intensity normalization, and alignment.

Article Snippet: To remedy this problem, we developed a custom dewarping program (Supplementary File ) in MATLAB (The MathWorks, Inc., Natick, MA, United States) that interfaced with Imaris (Bitplane AG, Zurich, Switzerland) via the ImarisXT feature.

Techniques:

Journal: Frontiers in Neuroscience

Article Title: 3D Reconstruction of the Intracortical Volume Around a Hybrid Microelectrode Array

doi: 10.3389/fnins.2019.00393

Figure Lengend Snippet: (A) 3D volume rendering of GFAP (green) and NeuN (magenta) after stitching, cropping, and stacking. Dewarping, alignment, and intensity normalization have not yet been performed. (B) Vertical cross section through the 3D volume. The dark bands are dark, out-of-focus optical slices above and below the actual tissue in each section.

Techniques:

Journal: Frontiers in Neuroscience

Article Title: 3D Reconstruction of the Intracortical Volume Around a Hybrid Microelectrode Array

doi: 10.3389/fnins.2019.00393

Figure Lengend Snippet: (A) Schematic of the dewarping algorithm. The brightest contiguous subset of voxels in z is retained while the rest are discarded, resulting in a flatter section. (B) Vertical cross section through a section before dewarping with height scaled 10×. The section is tilted, has a large wrinkle, and has a stitching artifact. (C) After dewarping the tissue is nearly flat (height still scaled 10×).

Techniques:

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1) Product Images from "3D Reconstruction of the Intracortical Volume Around a Hybrid Microelectrode Array"

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