tracking algorithm Search Results


angular momentum for eddy detection and tracking algorithm  (Ameda Labordiagnostik)
90
Ameda Labordiagnostik angular momentum for eddy detection and tracking algorithm
Angular Momentum For Eddy Detection And Tracking Algorithm, supplied by Ameda Labordiagnostik, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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angular momentum for eddy detection and tracking algorithm - by Bioz Stars, 2026-06
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speckle-tracking algorithm vevostrain  (FUJIFILM VisualSonics Inc)
90
FUJIFILM VisualSonics Inc speckle-tracking algorithm vevostrain
Speckle Tracking Algorithm Vevostrain, supplied by FUJIFILM VisualSonics 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/speckle-tracking algorithm vevostrain/product/FUJIFILM VisualSonics Inc
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speckle-tracking algorithm vevostrain - by Bioz Stars, 2026-06
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diogenes feature tracking software  (TOMTEC IMAGING SYSTEMS GMBH)
90
TOMTEC IMAGING SYSTEMS GMBH diogenes feature tracking software
Propagated contours and reported <t>feature</t> <t>tracking</t> strains are inconsistent (representative subject). The propagated endocardial contours for frame 1 and frame 30 (the last frame) of a representative subject are shown along with the strains reported by feature tracking. Despite the differences in contour length, which would be measured as strain by the contour-based calculation, the feature tracking <t>software</t> reported zero strain in all segments and, thus, zero slice-wise strain. When deriving strains, the feature tracking software may employ curve-fitting after propagating the contours, which would lead to differences between the reported feature tracking strains and the contour-based strains
Diogenes Feature Tracking Software, supplied by TOMTEC IMAGING SYSTEMS GMBH, 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/diogenes feature tracking software/product/TOMTEC IMAGING SYSTEMS GMBH
Average 90 stars, based on 1 article reviews
diogenes feature tracking software - by Bioz Stars, 2026-06
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tracking algorithm  (SourceForge net)
90
SourceForge net tracking algorithm
Propagated contours and reported <t>feature</t> <t>tracking</t> strains are inconsistent (representative subject). The propagated endocardial contours for frame 1 and frame 30 (the last frame) of a representative subject are shown along with the strains reported by feature tracking. Despite the differences in contour length, which would be measured as strain by the contour-based calculation, the feature tracking <t>software</t> reported zero strain in all segments and, thus, zero slice-wise strain. When deriving strains, the feature tracking software may employ curve-fitting after propagating the contours, which would lead to differences between the reported feature tracking strains and the contour-based strains
Tracking Algorithm, supplied by SourceForge net, 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/tracking algorithm/product/SourceForge net
Average 90 stars, based on 1 article reviews
tracking algorithm - by Bioz Stars, 2026-06
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trackobj particle-tracking algorithm  (MetaMorph Inc)
90
MetaMorph Inc trackobj particle-tracking algorithm
Propagated contours and reported <t>feature</t> <t>tracking</t> strains are inconsistent (representative subject). The propagated endocardial contours for frame 1 and frame 30 (the last frame) of a representative subject are shown along with the strains reported by feature tracking. Despite the differences in contour length, which would be measured as strain by the contour-based calculation, the feature tracking <t>software</t> reported zero strain in all segments and, thus, zero slice-wise strain. When deriving strains, the feature tracking software may employ curve-fitting after propagating the contours, which would lead to differences between the reported feature tracking strains and the contour-based strains
Trackobj Particle Tracking Algorithm, supplied by MetaMorph 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/trackobj particle-tracking algorithm/product/MetaMorph Inc
Average 90 stars, based on 1 article reviews
trackobj particle-tracking algorithm - by Bioz Stars, 2026-06
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alpha–beta tracking algorithm  (Myriax Pty Ltd)
90
Myriax Pty Ltd alpha–beta tracking algorithm
Propagated contours and reported <t>feature</t> <t>tracking</t> strains are inconsistent (representative subject). The propagated endocardial contours for frame 1 and frame 30 (the last frame) of a representative subject are shown along with the strains reported by feature tracking. Despite the differences in contour length, which would be measured as strain by the contour-based calculation, the feature tracking <t>software</t> reported zero strain in all segments and, thus, zero slice-wise strain. When deriving strains, the feature tracking software may employ curve-fitting after propagating the contours, which would lead to differences between the reported feature tracking strains and the contour-based strains
Alpha–Beta Tracking Algorithm, supplied by Myriax Pty Ltd, 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/alpha–beta tracking algorithm/product/Myriax Pty Ltd
Average 90 stars, based on 1 article reviews
alpha–beta tracking algorithm - by Bioz Stars, 2026-06
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particle-tracking image analysis algorithm  (universal imaging inc)
90
universal imaging inc particle-tracking image analysis algorithm
Organization of PBD binding sites relative to actin localization during FcγR-mediated phagocytosis. (A) Time series showing phase-contrast and Ratio images of a macrophage internalizing an IgG-opsonized erythrocyte. The color bar indicates the molar ratio (YFP/CFP). YFP-PBD was recruited to the forming phagosome (1.5–4.5 min) to a much greater extent during closure (5.0–7.5 min) and was cleared from the closed phagosome (8.5 min). (B) Particle-tracking analysis of YFP-actin (open circles) and YFP-PBD (closed circles) indicated that actin was recruited to the phagosome after particle binding (0–1 min) and during extension (1–5 min), and YFP-PBD was recruited throughout phagocytosis, with a pronounced increase in recruitment during closure (5.0–8 min). Data are mean ± SEM for 10 <t>phagocytic</t> events; no more than three events were taken from any one cell, and at least five different cells made up the 10 traces. (C) Simultaneous imaging of YFP-PBD and CFP-actin indicated that actin and the majority of PBD binding sites formed a discrete interface during constriction of the opsonized erythrocyte (constriction is inferred from the deformation of the erythrocyte; see arrow). CFP-actin was recruited to the forming phagosome, moved as a concentrated band over the particle during the extension phase (1.5–6.0 min), and condensed at the point of closure (6–7.5 min). YFP-PBD accumulated significantly on the base of the phagosome as constriction of the particle began (4.5–5.0 min), closely followed the moving band of actin during closure (5.5–7.5 min) and then rapidly dissipated (7.5–8.5 min). Bars, 3 μm. Also see Movie 1.
Particle Tracking Image Analysis Algorithm, supplied by universal imaging 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/particle-tracking image analysis algorithm/product/universal imaging inc
Average 90 stars, based on 1 article reviews
particle-tracking image analysis algorithm - by Bioz Stars, 2026-06
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tracking weight selection algorithm (twsa)  (OpenSim Ltd)
90
OpenSim Ltd tracking weight selection algorithm (twsa)
Organization of PBD binding sites relative to actin localization during FcγR-mediated phagocytosis. (A) Time series showing phase-contrast and Ratio images of a macrophage internalizing an IgG-opsonized erythrocyte. The color bar indicates the molar ratio (YFP/CFP). YFP-PBD was recruited to the forming phagosome (1.5–4.5 min) to a much greater extent during closure (5.0–7.5 min) and was cleared from the closed phagosome (8.5 min). (B) Particle-tracking analysis of YFP-actin (open circles) and YFP-PBD (closed circles) indicated that actin was recruited to the phagosome after particle binding (0–1 min) and during extension (1–5 min), and YFP-PBD was recruited throughout phagocytosis, with a pronounced increase in recruitment during closure (5.0–8 min). Data are mean ± SEM for 10 <t>phagocytic</t> events; no more than three events were taken from any one cell, and at least five different cells made up the 10 traces. (C) Simultaneous imaging of YFP-PBD and CFP-actin indicated that actin and the majority of PBD binding sites formed a discrete interface during constriction of the opsonized erythrocyte (constriction is inferred from the deformation of the erythrocyte; see arrow). CFP-actin was recruited to the forming phagosome, moved as a concentrated band over the particle during the extension phase (1.5–6.0 min), and condensed at the point of closure (6–7.5 min). YFP-PBD accumulated significantly on the base of the phagosome as constriction of the particle began (4.5–5.0 min), closely followed the moving band of actin during closure (5.5–7.5 min) and then rapidly dissipated (7.5–8.5 min). Bars, 3 μm. Also see Movie 1.
Tracking Weight Selection Algorithm (Twsa), supplied by OpenSim Ltd, 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/tracking weight selection algorithm (twsa)/product/OpenSim Ltd
Average 90 stars, based on 1 article reviews
tracking weight selection algorithm (twsa) - by Bioz Stars, 2026-06
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grain tracking algorithm  (OVITO GmbH)
90
OVITO GmbH grain tracking algorithm
Organization of PBD binding sites relative to actin localization during FcγR-mediated phagocytosis. (A) Time series showing phase-contrast and Ratio images of a macrophage internalizing an IgG-opsonized erythrocyte. The color bar indicates the molar ratio (YFP/CFP). YFP-PBD was recruited to the forming phagosome (1.5–4.5 min) to a much greater extent during closure (5.0–7.5 min) and was cleared from the closed phagosome (8.5 min). (B) Particle-tracking analysis of YFP-actin (open circles) and YFP-PBD (closed circles) indicated that actin was recruited to the phagosome after particle binding (0–1 min) and during extension (1–5 min), and YFP-PBD was recruited throughout phagocytosis, with a pronounced increase in recruitment during closure (5.0–8 min). Data are mean ± SEM for 10 <t>phagocytic</t> events; no more than three events were taken from any one cell, and at least five different cells made up the 10 traces. (C) Simultaneous imaging of YFP-PBD and CFP-actin indicated that actin and the majority of PBD binding sites formed a discrete interface during constriction of the opsonized erythrocyte (constriction is inferred from the deformation of the erythrocyte; see arrow). CFP-actin was recruited to the forming phagosome, moved as a concentrated band over the particle during the extension phase (1.5–6.0 min), and condensed at the point of closure (6–7.5 min). YFP-PBD accumulated significantly on the base of the phagosome as constriction of the particle began (4.5–5.0 min), closely followed the moving band of actin during closure (5.5–7.5 min) and then rapidly dissipated (7.5–8.5 min). Bars, 3 μm. Also see Movie 1.
Grain Tracking Algorithm, supplied by OVITO GmbH, 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/grain tracking algorithm/product/OVITO GmbH
Average 90 stars, based on 1 article reviews
grain tracking algorithm - by Bioz Stars, 2026-06
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tracking algorithms  (MultiTarget Pharmaceuticals)
90
MultiTarget Pharmaceuticals tracking algorithms
Organization of PBD binding sites relative to actin localization during FcγR-mediated phagocytosis. (A) Time series showing phase-contrast and Ratio images of a macrophage internalizing an IgG-opsonized erythrocyte. The color bar indicates the molar ratio (YFP/CFP). YFP-PBD was recruited to the forming phagosome (1.5–4.5 min) to a much greater extent during closure (5.0–7.5 min) and was cleared from the closed phagosome (8.5 min). (B) Particle-tracking analysis of YFP-actin (open circles) and YFP-PBD (closed circles) indicated that actin was recruited to the phagosome after particle binding (0–1 min) and during extension (1–5 min), and YFP-PBD was recruited throughout phagocytosis, with a pronounced increase in recruitment during closure (5.0–8 min). Data are mean ± SEM for 10 <t>phagocytic</t> events; no more than three events were taken from any one cell, and at least five different cells made up the 10 traces. (C) Simultaneous imaging of YFP-PBD and CFP-actin indicated that actin and the majority of PBD binding sites formed a discrete interface during constriction of the opsonized erythrocyte (constriction is inferred from the deformation of the erythrocyte; see arrow). CFP-actin was recruited to the forming phagosome, moved as a concentrated band over the particle during the extension phase (1.5–6.0 min), and condensed at the point of closure (6–7.5 min). YFP-PBD accumulated significantly on the base of the phagosome as constriction of the particle began (4.5–5.0 min), closely followed the moving band of actin during closure (5.5–7.5 min) and then rapidly dissipated (7.5–8.5 min). Bars, 3 μm. Also see Movie 1.
Tracking Algorithms, supplied by MultiTarget Pharmaceuticals, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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tracking algorithms - by Bioz Stars, 2026-06
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non-linearity control algorithm for uav target tracking based on fuzzy logic systems  (microSYST Systemelectronic GmbH)
90
microSYST Systemelectronic GmbH non-linearity control algorithm for uav target tracking based on fuzzy logic systems
Organization of PBD binding sites relative to actin localization during FcγR-mediated phagocytosis. (A) Time series showing phase-contrast and Ratio images of a macrophage internalizing an IgG-opsonized erythrocyte. The color bar indicates the molar ratio (YFP/CFP). YFP-PBD was recruited to the forming phagosome (1.5–4.5 min) to a much greater extent during closure (5.0–7.5 min) and was cleared from the closed phagosome (8.5 min). (B) Particle-tracking analysis of YFP-actin (open circles) and YFP-PBD (closed circles) indicated that actin was recruited to the phagosome after particle binding (0–1 min) and during extension (1–5 min), and YFP-PBD was recruited throughout phagocytosis, with a pronounced increase in recruitment during closure (5.0–8 min). Data are mean ± SEM for 10 <t>phagocytic</t> events; no more than three events were taken from any one cell, and at least five different cells made up the 10 traces. (C) Simultaneous imaging of YFP-PBD and CFP-actin indicated that actin and the majority of PBD binding sites formed a discrete interface during constriction of the opsonized erythrocyte (constriction is inferred from the deformation of the erythrocyte; see arrow). CFP-actin was recruited to the forming phagosome, moved as a concentrated band over the particle during the extension phase (1.5–6.0 min), and condensed at the point of closure (6–7.5 min). YFP-PBD accumulated significantly on the base of the phagosome as constriction of the particle began (4.5–5.0 min), closely followed the moving band of actin during closure (5.5–7.5 min) and then rapidly dissipated (7.5–8.5 min). Bars, 3 μm. Also see Movie 1.
Non Linearity Control Algorithm For Uav Target Tracking Based On Fuzzy Logic Systems, supplied by microSYST Systemelectronic GmbH, 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/non-linearity control algorithm for uav target tracking based on fuzzy logic systems/product/microSYST Systemelectronic GmbH
Average 90 stars, based on 1 article reviews
non-linearity control algorithm for uav target tracking based on fuzzy logic systems - by Bioz Stars, 2026-06
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automatic particle tracking scheme  (ANSYS inc)
90
ANSYS inc automatic particle tracking scheme
Organization of PBD binding sites relative to actin localization during FcγR-mediated phagocytosis. (A) Time series showing phase-contrast and Ratio images of a macrophage internalizing an IgG-opsonized erythrocyte. The color bar indicates the molar ratio (YFP/CFP). YFP-PBD was recruited to the forming phagosome (1.5–4.5 min) to a much greater extent during closure (5.0–7.5 min) and was cleared from the closed phagosome (8.5 min). (B) Particle-tracking analysis of YFP-actin (open circles) and YFP-PBD (closed circles) indicated that actin was recruited to the phagosome after particle binding (0–1 min) and during extension (1–5 min), and YFP-PBD was recruited throughout phagocytosis, with a pronounced increase in recruitment during closure (5.0–8 min). Data are mean ± SEM for 10 <t>phagocytic</t> events; no more than three events were taken from any one cell, and at least five different cells made up the 10 traces. (C) Simultaneous imaging of YFP-PBD and CFP-actin indicated that actin and the majority of PBD binding sites formed a discrete interface during constriction of the opsonized erythrocyte (constriction is inferred from the deformation of the erythrocyte; see arrow). CFP-actin was recruited to the forming phagosome, moved as a concentrated band over the particle during the extension phase (1.5–6.0 min), and condensed at the point of closure (6–7.5 min). YFP-PBD accumulated significantly on the base of the phagosome as constriction of the particle began (4.5–5.0 min), closely followed the moving band of actin during closure (5.5–7.5 min) and then rapidly dissipated (7.5–8.5 min). Bars, 3 μm. Also see Movie 1.
Automatic Particle Tracking Scheme, supplied by ANSYS 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/automatic particle tracking scheme/product/ANSYS inc
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Image Search Results


Propagated contours and reported feature tracking strains are inconsistent (representative subject). The propagated endocardial contours for frame 1 and frame 30 (the last frame) of a representative subject are shown along with the strains reported by feature tracking. Despite the differences in contour length, which would be measured as strain by the contour-based calculation, the feature tracking software reported zero strain in all segments and, thus, zero slice-wise strain. When deriving strains, the feature tracking software may employ curve-fitting after propagating the contours, which would lead to differences between the reported feature tracking strains and the contour-based strains

Journal: Journal of Cardiovascular Magnetic Resonance

Article Title: Comparison of left ventricular strains and torsion derived from feature tracking and DENSE CMR

doi: 10.1186/s12968-018-0485-4

Figure Lengend Snippet: Propagated contours and reported feature tracking strains are inconsistent (representative subject). The propagated endocardial contours for frame 1 and frame 30 (the last frame) of a representative subject are shown along with the strains reported by feature tracking. Despite the differences in contour length, which would be measured as strain by the contour-based calculation, the feature tracking software reported zero strain in all segments and, thus, zero slice-wise strain. When deriving strains, the feature tracking software may employ curve-fitting after propagating the contours, which would lead to differences between the reported feature tracking strains and the contour-based strains

Article Snippet: Strain and twist were derived from bSSFP imaging with Diogenes feature tracking software (2D CPA MR, version 1.1.2.36, TomTec Imaging Systems, Munich, Germany).

Techniques: Software

Organization of PBD binding sites relative to actin localization during FcγR-mediated phagocytosis. (A) Time series showing phase-contrast and Ratio images of a macrophage internalizing an IgG-opsonized erythrocyte. The color bar indicates the molar ratio (YFP/CFP). YFP-PBD was recruited to the forming phagosome (1.5–4.5 min) to a much greater extent during closure (5.0–7.5 min) and was cleared from the closed phagosome (8.5 min). (B) Particle-tracking analysis of YFP-actin (open circles) and YFP-PBD (closed circles) indicated that actin was recruited to the phagosome after particle binding (0–1 min) and during extension (1–5 min), and YFP-PBD was recruited throughout phagocytosis, with a pronounced increase in recruitment during closure (5.0–8 min). Data are mean ± SEM for 10 phagocytic events; no more than three events were taken from any one cell, and at least five different cells made up the 10 traces. (C) Simultaneous imaging of YFP-PBD and CFP-actin indicated that actin and the majority of PBD binding sites formed a discrete interface during constriction of the opsonized erythrocyte (constriction is inferred from the deformation of the erythrocyte; see arrow). CFP-actin was recruited to the forming phagosome, moved as a concentrated band over the particle during the extension phase (1.5–6.0 min), and condensed at the point of closure (6–7.5 min). YFP-PBD accumulated significantly on the base of the phagosome as constriction of the particle began (4.5–5.0 min), closely followed the moving band of actin during closure (5.5–7.5 min) and then rapidly dissipated (7.5–8.5 min). Bars, 3 μm. Also see Movie 1.

Journal:

Article Title: Cdc42, Rac1, and Rac2 Display Distinct Patterns of Activation during Phagocytosis V⃞

doi: 10.1091/mbc.E03-11-0847

Figure Lengend Snippet: Organization of PBD binding sites relative to actin localization during FcγR-mediated phagocytosis. (A) Time series showing phase-contrast and Ratio images of a macrophage internalizing an IgG-opsonized erythrocyte. The color bar indicates the molar ratio (YFP/CFP). YFP-PBD was recruited to the forming phagosome (1.5–4.5 min) to a much greater extent during closure (5.0–7.5 min) and was cleared from the closed phagosome (8.5 min). (B) Particle-tracking analysis of YFP-actin (open circles) and YFP-PBD (closed circles) indicated that actin was recruited to the phagosome after particle binding (0–1 min) and during extension (1–5 min), and YFP-PBD was recruited throughout phagocytosis, with a pronounced increase in recruitment during closure (5.0–8 min). Data are mean ± SEM for 10 phagocytic events; no more than three events were taken from any one cell, and at least five different cells made up the 10 traces. (C) Simultaneous imaging of YFP-PBD and CFP-actin indicated that actin and the majority of PBD binding sites formed a discrete interface during constriction of the opsonized erythrocyte (constriction is inferred from the deformation of the erythrocyte; see arrow). CFP-actin was recruited to the forming phagosome, moved as a concentrated band over the particle during the extension phase (1.5–6.0 min), and condensed at the point of closure (6–7.5 min). YFP-PBD accumulated significantly on the base of the phagosome as constriction of the particle began (4.5–5.0 min), closely followed the moving band of actin during closure (5.5–7.5 min) and then rapidly dissipated (7.5–8.5 min). Bars, 3 μm. Also see Movie 1.

Article Snippet: To quantify signaling events from multiple phagocytic events, a particle-tracking image analysis algorithm was developed in MetaMorph software (Universal Imaging).

Techniques: Binding Assay, Imaging

Ratiometric imaging and tracking analysis of YFP-Cdc42, YFP-Rac1, YFP-Rac2, and YFP-AtkPH domain relative to CFP during phagocytosis. (A, C, E, and G) Phase-contrast, YFP, and Ratio image time series of RAW macrophages phagocytosing IgG-coated erythrocytes. Color bars indicate the ranges of the Ratio values. (B, D, F, and H) Plots of RP/RC indicating the dynamics of YFP-chimera localization to phagosomes, averaged for 10 phagocytic events each. Error bars are the SE of the mean. (A) YFP-Cdc42 was present at the site of binding (0.5 min), localized to the tips of the advancing pseudopod (1.5–4.5 min) and then remained on the phagosome during and following closure (5.5–8.5 min). (B) Tracking analysis indicated the enhancement of YFP-Cdc42 on multiple phagosomes, but it did not indicate a significant change in localization. (C) YFP-Rac1 was present on plasma membranes before phagocytosis as seen by the Ratio image (0.5 min). The ratio increased as membrane extended around the particle (1.5–4.5 min) and then diminished somewhat during internalization (5.5–8.5 min). (D) Cumulative tracking data indicated that the association of YFP-Rac1 with the phagosome was variable, decreased until closure (>8.0 min) and then remained slightly elevated. (E) YFP-Rac2 localized to the base of the phagosome during extension and closure. (F) Tracking analysis showed YFP-Rac2 slightly increased on the phagosome. (G) The YFP-AktPH domain localized rapidly to the site of particle contact (0.5–1.5 min), continually increased (1.5–4.5 min), and then was cleared from the plasma membrane after closure (5.5–8.5 min). (H) YFP-AktPH was localized to phagosomes throughout formation and closure and then was cleared slowly. Bar, 3 μm.

Journal:

Article Title: Cdc42, Rac1, and Rac2 Display Distinct Patterns of Activation during Phagocytosis V⃞

doi: 10.1091/mbc.E03-11-0847

Figure Lengend Snippet: Ratiometric imaging and tracking analysis of YFP-Cdc42, YFP-Rac1, YFP-Rac2, and YFP-AtkPH domain relative to CFP during phagocytosis. (A, C, E, and G) Phase-contrast, YFP, and Ratio image time series of RAW macrophages phagocytosing IgG-coated erythrocytes. Color bars indicate the ranges of the Ratio values. (B, D, F, and H) Plots of RP/RC indicating the dynamics of YFP-chimera localization to phagosomes, averaged for 10 phagocytic events each. Error bars are the SE of the mean. (A) YFP-Cdc42 was present at the site of binding (0.5 min), localized to the tips of the advancing pseudopod (1.5–4.5 min) and then remained on the phagosome during and following closure (5.5–8.5 min). (B) Tracking analysis indicated the enhancement of YFP-Cdc42 on multiple phagosomes, but it did not indicate a significant change in localization. (C) YFP-Rac1 was present on plasma membranes before phagocytosis as seen by the Ratio image (0.5 min). The ratio increased as membrane extended around the particle (1.5–4.5 min) and then diminished somewhat during internalization (5.5–8.5 min). (D) Cumulative tracking data indicated that the association of YFP-Rac1 with the phagosome was variable, decreased until closure (>8.0 min) and then remained slightly elevated. (E) YFP-Rac2 localized to the base of the phagosome during extension and closure. (F) Tracking analysis showed YFP-Rac2 slightly increased on the phagosome. (G) The YFP-AktPH domain localized rapidly to the site of particle contact (0.5–1.5 min), continually increased (1.5–4.5 min), and then was cleared from the plasma membrane after closure (5.5–8.5 min). (H) YFP-AktPH was localized to phagosomes throughout formation and closure and then was cleared slowly. Bar, 3 μm.

Article Snippet: To quantify signaling events from multiple phagocytic events, a particle-tracking image analysis algorithm was developed in MetaMorph software (Universal Imaging).

Techniques: Imaging, Binding Assay, Clinical Proteomics, Membrane

FRET stoichiometric imaging of YFP-Cdc42, YFP-Rac1, and YFP-Rac2 activation during phagocytosis of E-IgG. (A) Phase-contrast and EA images for cells expressing YFP-Cdc42 and CFP-PBD. YFP-Cdc42 produced an EA signal as soon as the erythrocyte contacted the macrophage. The high EA was restricted to the advancing tip of the pseudopod as it moved over the particle (1.5–5.5 min) and diminished during the closure phase (5.5–8.5 min). (B) Tracking analysis indicated the rapid association of YFP-Cdc42 with CFP-PBD and persistent FRET throughout pseudopod extension. (C and D) FRET microscopy and stoichiometry of macrophages expressing YFP-Rac1 and CFP-PBD. YFP-Rac1 interacted with CFP-PBD shortly after particle binding and throughout the pseudopod during extension (1.5–5.5 min). The quantity of YFP-Rac1 in complex with CFP-PBD increased transiently on the base of the pseudopod during the closure phase (5.5–7.5 min) and was deactivated on the closed phagosome (8.5 min). (D) This response was consistent when averaged over multiple phagocytic events. (E and F) FRET microscopy of cells expressing YFP-Rac2 and CFP-PBD indicated that Rac2 activation was delayed until closure. (G) Control cell expressing YFP-Cdc42 and CFP showed a uniform value of EA = 0 throughout phagocytosis. (H) Averaged traces from control cells expressing CFP plus YFP-Cdc42 (red), YFP-Rac1 (blue), or YFP-Rac2 (green) never indicated FRET. Bar, 3 μm. Also see Movies 2–4.

Journal:

Article Title: Cdc42, Rac1, and Rac2 Display Distinct Patterns of Activation during Phagocytosis V⃞

doi: 10.1091/mbc.E03-11-0847

Figure Lengend Snippet: FRET stoichiometric imaging of YFP-Cdc42, YFP-Rac1, and YFP-Rac2 activation during phagocytosis of E-IgG. (A) Phase-contrast and EA images for cells expressing YFP-Cdc42 and CFP-PBD. YFP-Cdc42 produced an EA signal as soon as the erythrocyte contacted the macrophage. The high EA was restricted to the advancing tip of the pseudopod as it moved over the particle (1.5–5.5 min) and diminished during the closure phase (5.5–8.5 min). (B) Tracking analysis indicated the rapid association of YFP-Cdc42 with CFP-PBD and persistent FRET throughout pseudopod extension. (C and D) FRET microscopy and stoichiometry of macrophages expressing YFP-Rac1 and CFP-PBD. YFP-Rac1 interacted with CFP-PBD shortly after particle binding and throughout the pseudopod during extension (1.5–5.5 min). The quantity of YFP-Rac1 in complex with CFP-PBD increased transiently on the base of the pseudopod during the closure phase (5.5–7.5 min) and was deactivated on the closed phagosome (8.5 min). (D) This response was consistent when averaged over multiple phagocytic events. (E and F) FRET microscopy of cells expressing YFP-Rac2 and CFP-PBD indicated that Rac2 activation was delayed until closure. (G) Control cell expressing YFP-Cdc42 and CFP showed a uniform value of EA = 0 throughout phagocytosis. (H) Averaged traces from control cells expressing CFP plus YFP-Cdc42 (red), YFP-Rac1 (blue), or YFP-Rac2 (green) never indicated FRET. Bar, 3 μm. Also see Movies 2–4.

Article Snippet: To quantify signaling events from multiple phagocytic events, a particle-tracking image analysis algorithm was developed in MetaMorph software (Universal Imaging).

Techniques: Imaging, Activation Assay, Expressing, Produced, Microscopy, Binding Assay, Control