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PMC2266719_F4_18755.jpg | Describe the main subject of this image. | Morphological rescue of some moe- embryonic defects by injection of the epb4.1l5 constructs. (A) In wild-type embryos at 60 hpf, brain ventricles are visible, and the RPE is uniform (inset). (B) In moe- embryos, brain ventricles are reduced in size or absent, pericaridal edema is pronounced, and the RPE is patchy (inse... |
PMC2266719_F4_18757.jpg | What is the principal component of this image? | Morphological rescue of some moe- embryonic defects by injection of the epb4.1l5 constructs. (A) In wild-type embryos at 60 hpf, brain ventricles are visible, and the RPE is uniform (inset). (B) In moe- embryos, brain ventricles are reduced in size or absent, pericaridal edema is pronounced, and the RPE is patchy (inse... |
PMC2266719_F4_18749.jpg | What can you see in this picture? | Morphological rescue of some moe- embryonic defects by injection of the epb4.1l5 constructs. (A) In wild-type embryos at 60 hpf, brain ventricles are visible, and the RPE is uniform (inset). (B) In moe- embryos, brain ventricles are reduced in size or absent, pericaridal edema is pronounced, and the RPE is patchy (inse... |
PMC2266719_F4_18760.jpg | What is the focal point of this photograph? | Morphological rescue of some moe- embryonic defects by injection of the epb4.1l5 constructs. (A) In wild-type embryos at 60 hpf, brain ventricles are visible, and the RPE is uniform (inset). (B) In moe- embryos, brain ventricles are reduced in size or absent, pericaridal edema is pronounced, and the RPE is patchy (inse... |
PMC2266719_F4_18751.jpg | What does this image primarily show? | Morphological rescue of some moe- embryonic defects by injection of the epb4.1l5 constructs. (A) In wild-type embryos at 60 hpf, brain ventricles are visible, and the RPE is uniform (inset). (B) In moe- embryos, brain ventricles are reduced in size or absent, pericaridal edema is pronounced, and the RPE is patchy (inse... |
PMC2266719_F4_18759.jpg | What is shown in this image? | Morphological rescue of some moe- embryonic defects by injection of the epb4.1l5 constructs. (A) In wild-type embryos at 60 hpf, brain ventricles are visible, and the RPE is uniform (inset). (B) In moe- embryos, brain ventricles are reduced in size or absent, pericaridal edema is pronounced, and the RPE is patchy (inse... |
PMC2266719_F4_18758.jpg | What does this image primarily show? | Morphological rescue of some moe- embryonic defects by injection of the epb4.1l5 constructs. (A) In wild-type embryos at 60 hpf, brain ventricles are visible, and the RPE is uniform (inset). (B) In moe- embryos, brain ventricles are reduced in size or absent, pericaridal edema is pronounced, and the RPE is patchy (inse... |
PMC2266719_F4_18756.jpg | What's the most prominent thing you notice in this picture? | Morphological rescue of some moe- embryonic defects by injection of the epb4.1l5 constructs. (A) In wild-type embryos at 60 hpf, brain ventricles are visible, and the RPE is uniform (inset). (B) In moe- embryos, brain ventricles are reduced in size or absent, pericaridal edema is pronounced, and the RPE is patchy (inse... |
PMC2266719_F5_18767.jpg | What's the most prominent thing you notice in this picture? | Injection of epb4.1l5long mRNA into moe- mutants restores retinal lamination but not normal photoreceptor morphology at 6 dpf. In wild-type (A) and epb4.1l5long mRNA injected moe- mutants (C), Müller glial cells are radially oriented (labeled with anti-Carbonic Anhydrase II, red), and GFP+ rods and double cones (ZPR-1 ... |
PMC2266719_F5_18772.jpg | What key item or scene is captured in this photo? | Injection of epb4.1l5long mRNA into moe- mutants restores retinal lamination but not normal photoreceptor morphology at 6 dpf. In wild-type (A) and epb4.1l5long mRNA injected moe- mutants (C), Müller glial cells are radially oriented (labeled with anti-Carbonic Anhydrase II, red), and GFP+ rods and double cones (ZPR-1 ... |
PMC2266719_F5_18768.jpg | What is the main focus of this visual representation? | Injection of epb4.1l5long mRNA into moe- mutants restores retinal lamination but not normal photoreceptor morphology at 6 dpf. In wild-type (A) and epb4.1l5long mRNA injected moe- mutants (C), Müller glial cells are radially oriented (labeled with anti-Carbonic Anhydrase II, red), and GFP+ rods and double cones (ZPR-1 ... |
PMC2266719_F5_18765.jpg | What is being portrayed in this visual content? | Injection of epb4.1l5long mRNA into moe- mutants restores retinal lamination but not normal photoreceptor morphology at 6 dpf. In wild-type (A) and epb4.1l5long mRNA injected moe- mutants (C), Müller glial cells are radially oriented (labeled with anti-Carbonic Anhydrase II, red), and GFP+ rods and double cones (ZPR-1 ... |
PMC2266719_F5_18766.jpg | What does this image primarily show? | Injection of epb4.1l5long mRNA into moe- mutants restores retinal lamination but not normal photoreceptor morphology at 6 dpf. In wild-type (A) and epb4.1l5long mRNA injected moe- mutants (C), Müller glial cells are radially oriented (labeled with anti-Carbonic Anhydrase II, red), and GFP+ rods and double cones (ZPR-1 ... |
PMC2266744_F2_18776.jpg | What is the main focus of this visual representation? | Radiographic images of motion segments injected with radio-opaque medium 72 hours after incubation with 1, 5 or 10 mg/ml trypsin. |
PMC2266744_F2_18775.jpg | Describe the main subject of this image. | Radiographic images of motion segments injected with radio-opaque medium 72 hours after incubation with 1, 5 or 10 mg/ml trypsin. |
PMC2266753_F4_18781.jpg | What key item or scene is captured in this photo? | Fluorescence pattern of pig spermatozoa stained with FITC-PNA + PI for the assessment of acrosome status and sperm viability. Dead cells showing nuclear red PI fluorescence: C-D. Live cells without PI staining: A acrosome-reacted cells with uniform green FITC-PNA fluorescence of acrosome cap; B: acrosome-unreacted cell... |
PMC2266756_F1_18782.jpg | What is the dominant medical problem in this image? | One of the dot blots (exposing 2 min) showing enriched cDNAs hybridized to a digoxigenin-labeled probe generated from normalized in vivo cDNAs (upper) or normalized in vitro cDNAs (lower) after three rounds of SCOTS normalization. The dots at the same position in the two arrays were loaded with the same amplicon of eac... |
PMC2266756_F1_18783.jpg | Can you identify the primary element in this image? | One of the dot blots (exposing 2 min) showing enriched cDNAs hybridized to a digoxigenin-labeled probe generated from normalized in vivo cDNAs (upper) or normalized in vitro cDNAs (lower) after three rounds of SCOTS normalization. The dots at the same position in the two arrays were loaded with the same amplicon of eac... |
PMC2266759_F2_18786.jpg | What is the principal component of this image? | Maximum intensity projections of details from four of the stacks used for collection of spine data. The images are shown "raw" and have not undergone post-processing, such as contrast-enhancement (only rotation and resampling for screen-fit and printing purposes) (A-D). A screen shot of a three-dimensional (3-D) animat... |
PMC2266759_F2_18784.jpg | What stands out most in this visual? | Maximum intensity projections of details from four of the stacks used for collection of spine data. The images are shown "raw" and have not undergone post-processing, such as contrast-enhancement (only rotation and resampling for screen-fit and printing purposes) (A-D). A screen shot of a three-dimensional (3-D) animat... |
PMC2266759_F2_18787.jpg | Describe the main subject of this image. | Maximum intensity projections of details from four of the stacks used for collection of spine data. The images are shown "raw" and have not undergone post-processing, such as contrast-enhancement (only rotation and resampling for screen-fit and printing purposes) (A-D). A screen shot of a three-dimensional (3-D) animat... |
PMC2266762_F1_18790.jpg | What is the dominant medical problem in this image? | Immunohistochemical and FISH analysis of EGFR and HER2-neu on ovarian tumours. A-C : Immunohistochemistry for EGFR and HER2-neu protein expression on paraffin sections from ovarian tumours (all 400× magnification). Examples of an EGFR score 0 (A), EGFR 3+ overexpression (B) and HER2-neu 3+ overexpression (C). D-F : Flu... |
PMC2266762_F1_18789.jpg | What is shown in this image? | Immunohistochemical and FISH analysis of EGFR and HER2-neu on ovarian tumours. A-C : Immunohistochemistry for EGFR and HER2-neu protein expression on paraffin sections from ovarian tumours (all 400× magnification). Examples of an EGFR score 0 (A), EGFR 3+ overexpression (B) and HER2-neu 3+ overexpression (C). D-F : Flu... |
PMC2266762_F1_18793.jpg | What is the principal component of this image? | Immunohistochemical and FISH analysis of EGFR and HER2-neu on ovarian tumours. A-C : Immunohistochemistry for EGFR and HER2-neu protein expression on paraffin sections from ovarian tumours (all 400× magnification). Examples of an EGFR score 0 (A), EGFR 3+ overexpression (B) and HER2-neu 3+ overexpression (C). D-F : Flu... |
PMC2266762_F1_18791.jpg | What does this image primarily show? | Immunohistochemical and FISH analysis of EGFR and HER2-neu on ovarian tumours. A-C : Immunohistochemistry for EGFR and HER2-neu protein expression on paraffin sections from ovarian tumours (all 400× magnification). Examples of an EGFR score 0 (A), EGFR 3+ overexpression (B) and HER2-neu 3+ overexpression (C). D-F : Flu... |
PMC2266762_F1_18794.jpg | What object or scene is depicted here? | Immunohistochemical and FISH analysis of EGFR and HER2-neu on ovarian tumours. A-C : Immunohistochemistry for EGFR and HER2-neu protein expression on paraffin sections from ovarian tumours (all 400× magnification). Examples of an EGFR score 0 (A), EGFR 3+ overexpression (B) and HER2-neu 3+ overexpression (C). D-F : Flu... |
PMC2266762_F1_18792.jpg | What is the principal component of this image? | Immunohistochemical and FISH analysis of EGFR and HER2-neu on ovarian tumours. A-C : Immunohistochemistry for EGFR and HER2-neu protein expression on paraffin sections from ovarian tumours (all 400× magnification). Examples of an EGFR score 0 (A), EGFR 3+ overexpression (B) and HER2-neu 3+ overexpression (C). D-F : Flu... |
PMC2266766_F1_18795.jpg | What does this image primarily show? | Photograph of an indurated, crusted lesion with central ulceration giving the lip a bitten off appearance. |
PMC2266767_F1_18796.jpg | What is shown in this image? | Radiograph post peripherally inserted central venous line insertion. |
PMC2266767_F2_18797.jpg | What is the core subject represented in this visual? | Radiograph taken following episode of aspiration requiring intubation. |
PMC2266777_F2_18800.jpg | What key item or scene is captured in this photo? | Computed tomogram of abdomen showing right psoas abscess extending from above the right kidney. |
PMC2266810_fig1_18803.jpg | What is the principal component of this image? | TMS coil
was located over (a) the right DL-PFC (X = 45, Y = 33, Z = 25) or (b) the vertex (control) (X = 0, Y = −35, Z = 80). The positioning of the TMS coil over these
locations, marked on the native MRI, was performed with the aid of a frameless
stereotaxic system. |
PMC2266810_fig1_18801.jpg | What is shown in this image? | TMS coil
was located over (a) the right DL-PFC (X = 45, Y = 33, Z = 25) or (b) the vertex (control) (X = 0, Y = −35, Z = 80). The positioning of the TMS coil over these
locations, marked on the native MRI, was performed with the aid of a frameless
stereotaxic system. |
PMC2266810_fig1_18804.jpg | What is the principal component of this image? | TMS coil
was located over (a) the right DL-PFC (X = 45, Y = 33, Z = 25) or (b) the vertex (control) (X = 0, Y = −35, Z = 80). The positioning of the TMS coil over these
locations, marked on the native MRI, was performed with the aid of a frameless
stereotaxic system. |
PMC2266810_fig1_18802.jpg | What is the central feature of this picture? | TMS coil
was located over (a) the right DL-PFC (X = 45, Y = 33, Z = 25) or (b) the vertex (control) (X = 0, Y = −35, Z = 80). The positioning of the TMS coil over these
locations, marked on the native MRI, was performed with the aid of a frameless
stereotaxic system. |
PMC2266813_fig1_18805.jpg | What is the dominant medical problem in this image? | Mixed-effects response maps for BOLD and flow changes in response
to monocular and binocular visual stimulation (n = 6). Spatial extent and
intensity are
greater for binocular stimulation than for monocular, for both BOLD and flow
signals. Thresholded activation maps are overlaid on average T1 maps for the
six subjects... |
PMC2266813_fig1_18806.jpg | What is the core subject represented in this visual? | Mixed-effects response maps for BOLD and flow changes in response
to monocular and binocular visual stimulation (n = 6). Spatial extent and
intensity are
greater for binocular stimulation than for monocular, for both BOLD and flow
signals. Thresholded activation maps are overlaid on average T1 maps for the
six subjects... |
PMC2266840_fig1_18808.jpg | What does this image primarily show? | Immunohistochemical examination of Smac (A, C) and XIAP (B, D) in normal kidney (A, B) and RCC (C, D). In normal kidney, Smac expression was detected in tubular epithelial cells, Bowman capsule cells, and a portion of glomerular cells (A). In tumours, Smac staining was weaker than in normal kidney (C). XIAP expression ... |
PMC2266840_fig1_18810.jpg | What is the dominant medical problem in this image? | Immunohistochemical examination of Smac (A, C) and XIAP (B, D) in normal kidney (A, B) and RCC (C, D). In normal kidney, Smac expression was detected in tubular epithelial cells, Bowman capsule cells, and a portion of glomerular cells (A). In tumours, Smac staining was weaker than in normal kidney (C). XIAP expression ... |
PMC2266840_fig1_18809.jpg | What is the dominant medical problem in this image? | Immunohistochemical examination of Smac (A, C) and XIAP (B, D) in normal kidney (A, B) and RCC (C, D). In normal kidney, Smac expression was detected in tubular epithelial cells, Bowman capsule cells, and a portion of glomerular cells (A). In tumours, Smac staining was weaker than in normal kidney (C). XIAP expression ... |
PMC2266845_fig1_18816.jpg | What is the main focus of this visual representation? | Cortactin expression in normal oral mucosa and HNSCC. Staining of cortactin was performed as indicated in Materials and Methods. Normal epithelium (A–B) is devoid of staining, arrowheads indicate cortactin staining of blood vessels. Scale bar represents 200 μm in the tissue core shown in panel A and 100 μm in the highe... |
PMC2266845_fig1_18813.jpg | What key item or scene is captured in this photo? | Cortactin expression in normal oral mucosa and HNSCC. Staining of cortactin was performed as indicated in Materials and Methods. Normal epithelium (A–B) is devoid of staining, arrowheads indicate cortactin staining of blood vessels. Scale bar represents 200 μm in the tissue core shown in panel A and 100 μm in the highe... |
PMC2266845_fig1_18814.jpg | What is being portrayed in this visual content? | Cortactin expression in normal oral mucosa and HNSCC. Staining of cortactin was performed as indicated in Materials and Methods. Normal epithelium (A–B) is devoid of staining, arrowheads indicate cortactin staining of blood vessels. Scale bar represents 200 μm in the tissue core shown in panel A and 100 μm in the highe... |
PMC2266845_fig1_18811.jpg | What is the core subject represented in this visual? | Cortactin expression in normal oral mucosa and HNSCC. Staining of cortactin was performed as indicated in Materials and Methods. Normal epithelium (A–B) is devoid of staining, arrowheads indicate cortactin staining of blood vessels. Scale bar represents 200 μm in the tissue core shown in panel A and 100 μm in the highe... |
PMC2266921_F6_18831.jpg | What is the dominant medical problem in this image? | The effects of transduction of various TAT-fused WASP peptides on sealing ring formation. Osteoclasts were transduced with indicated TAT-fused peptides or treated with PBS as a control. Confocal microscopy images of osteoclasts stained for actin are shown. Sealing ring was observed in osteoclasts treated with PBS (A) o... |
PMC2266921_F6_18830.jpg | What key item or scene is captured in this photo? | The effects of transduction of various TAT-fused WASP peptides on sealing ring formation. Osteoclasts were transduced with indicated TAT-fused peptides or treated with PBS as a control. Confocal microscopy images of osteoclasts stained for actin are shown. Sealing ring was observed in osteoclasts treated with PBS (A) o... |
PMC2266921_F6_18833.jpg | What is the central feature of this picture? | The effects of transduction of various TAT-fused WASP peptides on sealing ring formation. Osteoclasts were transduced with indicated TAT-fused peptides or treated with PBS as a control. Confocal microscopy images of osteoclasts stained for actin are shown. Sealing ring was observed in osteoclasts treated with PBS (A) o... |
PMC2266921_F6_18827.jpg | What is the dominant medical problem in this image? | The effects of transduction of various TAT-fused WASP peptides on sealing ring formation. Osteoclasts were transduced with indicated TAT-fused peptides or treated with PBS as a control. Confocal microscopy images of osteoclasts stained for actin are shown. Sealing ring was observed in osteoclasts treated with PBS (A) o... |
PMC2266921_F6_18835.jpg | What's the most prominent thing you notice in this picture? | The effects of transduction of various TAT-fused WASP peptides on sealing ring formation. Osteoclasts were transduced with indicated TAT-fused peptides or treated with PBS as a control. Confocal microscopy images of osteoclasts stained for actin are shown. Sealing ring was observed in osteoclasts treated with PBS (A) o... |
PMC2266921_F6_18829.jpg | Describe the main subject of this image. | The effects of transduction of various TAT-fused WASP peptides on sealing ring formation. Osteoclasts were transduced with indicated TAT-fused peptides or treated with PBS as a control. Confocal microscopy images of osteoclasts stained for actin are shown. Sealing ring was observed in osteoclasts treated with PBS (A) o... |
PMC2266921_F7_18825.jpg | What is the focal point of this photograph? | The effects of TAT-fused WASP peptides transduction on osteoclast bone resorption. Confocal images of the resorption pits are shown. Osteoclasts were transduced with indicated TAT-fused peptides (B-I) or treated with PBS (A) for 48 h. Pits were scanned under confocal microscopy. Resorption pits were seen as dark spots.... |
PMC2266921_F7_18817.jpg | Describe the main subject of this image. | The effects of TAT-fused WASP peptides transduction on osteoclast bone resorption. Confocal images of the resorption pits are shown. Osteoclasts were transduced with indicated TAT-fused peptides (B-I) or treated with PBS (A) for 48 h. Pits were scanned under confocal microscopy. Resorption pits were seen as dark spots.... |
PMC2266921_F7_18824.jpg | What is the dominant medical problem in this image? | The effects of TAT-fused WASP peptides transduction on osteoclast bone resorption. Confocal images of the resorption pits are shown. Osteoclasts were transduced with indicated TAT-fused peptides (B-I) or treated with PBS (A) for 48 h. Pits were scanned under confocal microscopy. Resorption pits were seen as dark spots.... |
PMC2266921_F7_18823.jpg | What can you see in this picture? | The effects of TAT-fused WASP peptides transduction on osteoclast bone resorption. Confocal images of the resorption pits are shown. Osteoclasts were transduced with indicated TAT-fused peptides (B-I) or treated with PBS (A) for 48 h. Pits were scanned under confocal microscopy. Resorption pits were seen as dark spots.... |
PMC2266921_F7_18822.jpg | What is the central feature of this picture? | The effects of TAT-fused WASP peptides transduction on osteoclast bone resorption. Confocal images of the resorption pits are shown. Osteoclasts were transduced with indicated TAT-fused peptides (B-I) or treated with PBS (A) for 48 h. Pits were scanned under confocal microscopy. Resorption pits were seen as dark spots.... |
PMC2266921_F7_18819.jpg | What is the main focus of this visual representation? | The effects of TAT-fused WASP peptides transduction on osteoclast bone resorption. Confocal images of the resorption pits are shown. Osteoclasts were transduced with indicated TAT-fused peptides (B-I) or treated with PBS (A) for 48 h. Pits were scanned under confocal microscopy. Resorption pits were seen as dark spots.... |
PMC2266921_F7_18821.jpg | What is shown in this image? | The effects of TAT-fused WASP peptides transduction on osteoclast bone resorption. Confocal images of the resorption pits are shown. Osteoclasts were transduced with indicated TAT-fused peptides (B-I) or treated with PBS (A) for 48 h. Pits were scanned under confocal microscopy. Resorption pits were seen as dark spots.... |
PMC2266934_F1_18839.jpg | What is the dominant medical problem in this image? | Reflectance confocal microscopy (RCM) can visualize ductal epithelial cells during mammary gland development, growth, and aging. Prominent features distinguishable with RCM are (A-B) rudimentary primary ductal trees (open arrowheads), (C-D) terminal end buds (closed arrowheads), (E-I, P) secondary branching (thin arrow... |
PMC2266934_F1_18846.jpg | What is the principal component of this image? | Reflectance confocal microscopy (RCM) can visualize ductal epithelial cells during mammary gland development, growth, and aging. Prominent features distinguishable with RCM are (A-B) rudimentary primary ductal trees (open arrowheads), (C-D) terminal end buds (closed arrowheads), (E-I, P) secondary branching (thin arrow... |
PMC2266934_F1_18845.jpg | What is the core subject represented in this visual? | Reflectance confocal microscopy (RCM) can visualize ductal epithelial cells during mammary gland development, growth, and aging. Prominent features distinguishable with RCM are (A-B) rudimentary primary ductal trees (open arrowheads), (C-D) terminal end buds (closed arrowheads), (E-I, P) secondary branching (thin arrow... |
PMC2266934_F1_18843.jpg | Can you identify the primary element in this image? | Reflectance confocal microscopy (RCM) can visualize ductal epithelial cells during mammary gland development, growth, and aging. Prominent features distinguishable with RCM are (A-B) rudimentary primary ductal trees (open arrowheads), (C-D) terminal end buds (closed arrowheads), (E-I, P) secondary branching (thin arrow... |
PMC2266934_F1_18849.jpg | What is the dominant medical problem in this image? | Reflectance confocal microscopy (RCM) can visualize ductal epithelial cells during mammary gland development, growth, and aging. Prominent features distinguishable with RCM are (A-B) rudimentary primary ductal trees (open arrowheads), (C-D) terminal end buds (closed arrowheads), (E-I, P) secondary branching (thin arrow... |
PMC2266934_F1_18851.jpg | What key item or scene is captured in this photo? | Reflectance confocal microscopy (RCM) can visualize ductal epithelial cells during mammary gland development, growth, and aging. Prominent features distinguishable with RCM are (A-B) rudimentary primary ductal trees (open arrowheads), (C-D) terminal end buds (closed arrowheads), (E-I, P) secondary branching (thin arrow... |
PMC2266934_F1_18853.jpg | What key item or scene is captured in this photo? | Reflectance confocal microscopy (RCM) can visualize ductal epithelial cells during mammary gland development, growth, and aging. Prominent features distinguishable with RCM are (A-B) rudimentary primary ductal trees (open arrowheads), (C-D) terminal end buds (closed arrowheads), (E-I, P) secondary branching (thin arrow... |
PMC2266934_F1_18842.jpg | Describe the main subject of this image. | Reflectance confocal microscopy (RCM) can visualize ductal epithelial cells during mammary gland development, growth, and aging. Prominent features distinguishable with RCM are (A-B) rudimentary primary ductal trees (open arrowheads), (C-D) terminal end buds (closed arrowheads), (E-I, P) secondary branching (thin arrow... |
PMC2266934_F1_18840.jpg | What is being portrayed in this visual content? | Reflectance confocal microscopy (RCM) can visualize ductal epithelial cells during mammary gland development, growth, and aging. Prominent features distinguishable with RCM are (A-B) rudimentary primary ductal trees (open arrowheads), (C-D) terminal end buds (closed arrowheads), (E-I, P) secondary branching (thin arrow... |
PMC2266934_F1_18847.jpg | What does this image primarily show? | Reflectance confocal microscopy (RCM) can visualize ductal epithelial cells during mammary gland development, growth, and aging. Prominent features distinguishable with RCM are (A-B) rudimentary primary ductal trees (open arrowheads), (C-D) terminal end buds (closed arrowheads), (E-I, P) secondary branching (thin arrow... |
PMC2266934_F1_18838.jpg | What key item or scene is captured in this photo? | Reflectance confocal microscopy (RCM) can visualize ductal epithelial cells during mammary gland development, growth, and aging. Prominent features distinguishable with RCM are (A-B) rudimentary primary ductal trees (open arrowheads), (C-D) terminal end buds (closed arrowheads), (E-I, P) secondary branching (thin arrow... |
PMC2266934_F1_18848.jpg | What is being portrayed in this visual content? | Reflectance confocal microscopy (RCM) can visualize ductal epithelial cells during mammary gland development, growth, and aging. Prominent features distinguishable with RCM are (A-B) rudimentary primary ductal trees (open arrowheads), (C-D) terminal end buds (closed arrowheads), (E-I, P) secondary branching (thin arrow... |
PMC2266934_F1_18836.jpg | What stands out most in this visual? | Reflectance confocal microscopy (RCM) can visualize ductal epithelial cells during mammary gland development, growth, and aging. Prominent features distinguishable with RCM are (A-B) rudimentary primary ductal trees (open arrowheads), (C-D) terminal end buds (closed arrowheads), (E-I, P) secondary branching (thin arrow... |
PMC2266934_F1_18841.jpg | What is shown in this image? | Reflectance confocal microscopy (RCM) can visualize ductal epithelial cells during mammary gland development, growth, and aging. Prominent features distinguishable with RCM are (A-B) rudimentary primary ductal trees (open arrowheads), (C-D) terminal end buds (closed arrowheads), (E-I, P) secondary branching (thin arrow... |
PMC2266934_F1_18852.jpg | What is the core subject represented in this visual? | Reflectance confocal microscopy (RCM) can visualize ductal epithelial cells during mammary gland development, growth, and aging. Prominent features distinguishable with RCM are (A-B) rudimentary primary ductal trees (open arrowheads), (C-D) terminal end buds (closed arrowheads), (E-I, P) secondary branching (thin arrow... |
PMC2266934_F1_18844.jpg | What is the core subject represented in this visual? | Reflectance confocal microscopy (RCM) can visualize ductal epithelial cells during mammary gland development, growth, and aging. Prominent features distinguishable with RCM are (A-B) rudimentary primary ductal trees (open arrowheads), (C-D) terminal end buds (closed arrowheads), (E-I, P) secondary branching (thin arrow... |
PMC2266934_F2_18877.jpg | What is the focal point of this photograph? | RCM can image living tissue from mammary whole organ culture (WOC). Mammary glands from mice primed with an E&P pellet were either whole mounted immediately (uncultured) (A) or exposed to culture in IPAH supplemented media immediately (B-C). Other glands were put into IPAH culture after RCM imaging which was accomplish... |
PMC2266934_F2_18869.jpg | Describe the main subject of this image. | RCM can image living tissue from mammary whole organ culture (WOC). Mammary glands from mice primed with an E&P pellet were either whole mounted immediately (uncultured) (A) or exposed to culture in IPAH supplemented media immediately (B-C). Other glands were put into IPAH culture after RCM imaging which was accomplish... |
PMC2266934_F2_18874.jpg | Can you identify the primary element in this image? | RCM can image living tissue from mammary whole organ culture (WOC). Mammary glands from mice primed with an E&P pellet were either whole mounted immediately (uncultured) (A) or exposed to culture in IPAH supplemented media immediately (B-C). Other glands were put into IPAH culture after RCM imaging which was accomplish... |
PMC2266934_F2_18868.jpg | What is the core subject represented in this visual? | RCM can image living tissue from mammary whole organ culture (WOC). Mammary glands from mice primed with an E&P pellet were either whole mounted immediately (uncultured) (A) or exposed to culture in IPAH supplemented media immediately (B-C). Other glands were put into IPAH culture after RCM imaging which was accomplish... |
PMC2266934_F2_18873.jpg | What is the dominant medical problem in this image? | RCM can image living tissue from mammary whole organ culture (WOC). Mammary glands from mice primed with an E&P pellet were either whole mounted immediately (uncultured) (A) or exposed to culture in IPAH supplemented media immediately (B-C). Other glands were put into IPAH culture after RCM imaging which was accomplish... |
PMC2266934_F2_18875.jpg | What is the main focus of this visual representation? | RCM can image living tissue from mammary whole organ culture (WOC). Mammary glands from mice primed with an E&P pellet were either whole mounted immediately (uncultured) (A) or exposed to culture in IPAH supplemented media immediately (B-C). Other glands were put into IPAH culture after RCM imaging which was accomplish... |
PMC2266934_F2_18872.jpg | What stands out most in this visual? | RCM can image living tissue from mammary whole organ culture (WOC). Mammary glands from mice primed with an E&P pellet were either whole mounted immediately (uncultured) (A) or exposed to culture in IPAH supplemented media immediately (B-C). Other glands were put into IPAH culture after RCM imaging which was accomplish... |
PMC2266934_F2_18878.jpg | What's the most prominent thing you notice in this picture? | RCM can image living tissue from mammary whole organ culture (WOC). Mammary glands from mice primed with an E&P pellet were either whole mounted immediately (uncultured) (A) or exposed to culture in IPAH supplemented media immediately (B-C). Other glands were put into IPAH culture after RCM imaging which was accomplish... |
PMC2266934_F2_18870.jpg | What is the focal point of this photograph? | RCM can image living tissue from mammary whole organ culture (WOC). Mammary glands from mice primed with an E&P pellet were either whole mounted immediately (uncultured) (A) or exposed to culture in IPAH supplemented media immediately (B-C). Other glands were put into IPAH culture after RCM imaging which was accomplish... |
PMC2266934_F2_18866.jpg | What can you see in this picture? | RCM can image living tissue from mammary whole organ culture (WOC). Mammary glands from mice primed with an E&P pellet were either whole mounted immediately (uncultured) (A) or exposed to culture in IPAH supplemented media immediately (B-C). Other glands were put into IPAH culture after RCM imaging which was accomplish... |
PMC2266934_F2_18871.jpg | What is the central feature of this picture? | RCM can image living tissue from mammary whole organ culture (WOC). Mammary glands from mice primed with an E&P pellet were either whole mounted immediately (uncultured) (A) or exposed to culture in IPAH supplemented media immediately (B-C). Other glands were put into IPAH culture after RCM imaging which was accomplish... |
PMC2266934_F3_18854.jpg | What is the main focus of this visual representation? | GFP imaging can reveal details of ductal development, mammary tumors, tumor associated blood vessels, and lymph node morphology. Ductal development can be compared with two imaging techniques – by first GFP imaging the mammary gland (A, C) and then whole mounting the same gland (B, D). Mammary tumors appear less bright... |
PMC2266934_F3_18860.jpg | Describe the main subject of this image. | GFP imaging can reveal details of ductal development, mammary tumors, tumor associated blood vessels, and lymph node morphology. Ductal development can be compared with two imaging techniques – by first GFP imaging the mammary gland (A, C) and then whole mounting the same gland (B, D). Mammary tumors appear less bright... |
PMC2266934_F3_18864.jpg | What is the dominant medical problem in this image? | GFP imaging can reveal details of ductal development, mammary tumors, tumor associated blood vessels, and lymph node morphology. Ductal development can be compared with two imaging techniques – by first GFP imaging the mammary gland (A, C) and then whole mounting the same gland (B, D). Mammary tumors appear less bright... |
PMC2266934_F3_18856.jpg | What key item or scene is captured in this photo? | GFP imaging can reveal details of ductal development, mammary tumors, tumor associated blood vessels, and lymph node morphology. Ductal development can be compared with two imaging techniques – by first GFP imaging the mammary gland (A, C) and then whole mounting the same gland (B, D). Mammary tumors appear less bright... |
PMC2266934_F3_18859.jpg | What is shown in this image? | GFP imaging can reveal details of ductal development, mammary tumors, tumor associated blood vessels, and lymph node morphology. Ductal development can be compared with two imaging techniques – by first GFP imaging the mammary gland (A, C) and then whole mounting the same gland (B, D). Mammary tumors appear less bright... |
PMC2266934_F3_18857.jpg | What is the core subject represented in this visual? | GFP imaging can reveal details of ductal development, mammary tumors, tumor associated blood vessels, and lymph node morphology. Ductal development can be compared with two imaging techniques – by first GFP imaging the mammary gland (A, C) and then whole mounting the same gland (B, D). Mammary tumors appear less bright... |
PMC2266934_F3_18862.jpg | What can you see in this picture? | GFP imaging can reveal details of ductal development, mammary tumors, tumor associated blood vessels, and lymph node morphology. Ductal development can be compared with two imaging techniques – by first GFP imaging the mammary gland (A, C) and then whole mounting the same gland (B, D). Mammary tumors appear less bright... |
PMC2266934_F3_18855.jpg | What is the dominant medical problem in this image? | GFP imaging can reveal details of ductal development, mammary tumors, tumor associated blood vessels, and lymph node morphology. Ductal development can be compared with two imaging techniques – by first GFP imaging the mammary gland (A, C) and then whole mounting the same gland (B, D). Mammary tumors appear less bright... |
PMC2266934_F3_18861.jpg | What is shown in this image? | GFP imaging can reveal details of ductal development, mammary tumors, tumor associated blood vessels, and lymph node morphology. Ductal development can be compared with two imaging techniques – by first GFP imaging the mammary gland (A, C) and then whole mounting the same gland (B, D). Mammary tumors appear less bright... |
PMC2266934_F3_18858.jpg | What is the main focus of this visual representation? | GFP imaging can reveal details of ductal development, mammary tumors, tumor associated blood vessels, and lymph node morphology. Ductal development can be compared with two imaging techniques – by first GFP imaging the mammary gland (A, C) and then whole mounting the same gland (B, D). Mammary tumors appear less bright... |
PMC2266934_F4_18880.jpg | Can you identify the primary element in this image? | GFP fluorescence monitors ductal and alveolar development in WOC and during mammary gland transplantation. (A-D) Mammary glands were cultured in IPAH media for a total of 10 days. On days 0 (A), 3 (B), 7 (C), and 10 (D) the mammary glands were briefly removed from the incubator to examine alveolar development as visual... |
PMC2266934_F4_18884.jpg | What is the principal component of this image? | GFP fluorescence monitors ductal and alveolar development in WOC and during mammary gland transplantation. (A-D) Mammary glands were cultured in IPAH media for a total of 10 days. On days 0 (A), 3 (B), 7 (C), and 10 (D) the mammary glands were briefly removed from the incubator to examine alveolar development as visual... |
PMC2266934_F4_18879.jpg | What is the dominant medical problem in this image? | GFP fluorescence monitors ductal and alveolar development in WOC and during mammary gland transplantation. (A-D) Mammary glands were cultured in IPAH media for a total of 10 days. On days 0 (A), 3 (B), 7 (C), and 10 (D) the mammary glands were briefly removed from the incubator to examine alveolar development as visual... |
PMC2266934_F4_18882.jpg | What can you see in this picture? | GFP fluorescence monitors ductal and alveolar development in WOC and during mammary gland transplantation. (A-D) Mammary glands were cultured in IPAH media for a total of 10 days. On days 0 (A), 3 (B), 7 (C), and 10 (D) the mammary glands were briefly removed from the incubator to examine alveolar development as visual... |
PMC2266934_F4_18881.jpg | What is shown in this image? | GFP fluorescence monitors ductal and alveolar development in WOC and during mammary gland transplantation. (A-D) Mammary glands were cultured in IPAH media for a total of 10 days. On days 0 (A), 3 (B), 7 (C), and 10 (D) the mammary glands were briefly removed from the incubator to examine alveolar development as visual... |
PMC2266934_F4_18888.jpg | What object or scene is depicted here? | GFP fluorescence monitors ductal and alveolar development in WOC and during mammary gland transplantation. (A-D) Mammary glands were cultured in IPAH media for a total of 10 days. On days 0 (A), 3 (B), 7 (C), and 10 (D) the mammary glands were briefly removed from the incubator to examine alveolar development as visual... |
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