Fig. 4 FRESH printed scaffolds with complex internal and external architectures based on 3D imaging data from whole organs. FRESH printed scaffolds with.

Slides:

Advertisements

Similar presentations

Date of download: 6/3/2016 Copyright © 2016 SPIE. All rights reserved. (a) Confocal microscope images of human adipose-derived stem cells (hASCs) labeled.

Advertisements

IFT88 influences chondrocyte actin organization and biomechanics

Impaired lymphatic valve protrusion in Tie2Cre;Piezo1cKO mice.

Poly-GR and poly-PR co-aggregate with ribosomal proteins in C9orf72 patients. Poly-GR and poly-PR co-aggregate with ribosomal proteins in C9orf72 patients.

Elysse C. Filipe et al. BTS 2018;3:38-53

Confocal images of negative controls for Aβ42, Synaptophysin (syp), and PSD95 in hippocampal neurons. Confocal images of negative controls for Aβ42, Synaptophysin.

Fig. 1. Aberrant JNK pathway activation in mouse models of ALS and in spinal cord tissue from patients with sporadic ALS. Aberrant JNK pathway activation.

Immunofluorescence staining of virus-infected human placental explants

CD169+ macrophages play a critical role in mediating innate immune cell reorganization. CD169+ macrophages play a critical role in mediating innate immune.

Demonstration of MT sorting by integrating the top-down design of PDMS device with the bottom-up design of MT properties. Demonstration of MT sorting by.

Fig. 3 hESC-RPE cell sheet transplantation and validation of the surgical method. hESC-RPE cell sheet transplantation and validation of the surgical method.

CD169+ macrophages mediate Lm translocation to the splenic T cell zones. CD169+ macrophages mediate Lm translocation to the splenic T cell zones. (A) Confocal.

Fig. 3 Histomorphological evaluation of the segmental defect healing.

Cytosolic entry of Lm required for CD8α+ DC recruitment.

The effect of ETC duration and temperature on imaging depth.

Fig. 6 Combination therapy with LVSOD2 and LVshCTGF preserves flap volume and reduces fibrosis after RT. Combination therapy with LVSOD2 and LVshCTGF preserves.

Elysse C. Filipe et al. BTS 2018;3:38-53

Adenosine-induced osteogenic differentiation of hiPSCs involves A2bR

Fig. 1 Device structure, typical output performance, and cytocompatibility of BD-TENG. Device structure, typical output performance, and cytocompatibility.

Fig. 1. Overview of the nervous system of the adult S. roscoffensis.

Fig. 1. Representative images of the four cell lines using fluorescence microscopy. Representative images of the four cell lines using fluorescence microscopy.

Fig. 6. Cross-section of the stomach wall and spiral intestine of the embryo, stained with PAS. (A) Surface of the stomach wall (SW) and ingested material.

Fig. 5 In vivo MIP imaging of lipid and protein in C. elegans.

Fig. 4 Estimations of nonlinear functionals of a single-qubit state with the quantum Fredkin gate. Estimations of nonlinear functionals of a single-qubit.

Biocompatibility evaluation in vivo with a mouse subcutaneous implant

Fig. 4 3D reconfiguration of liquid metals for electronics.

Fig. 5 Metafluorophores with different photostability.

Fig. 1 High-resolution printing of liquid metals.

Fig. 1 3D vascular fabrication process.

Fig. 4. CIZ1 reduces the impact of injury to the heart.

Demonstration of MT sorting by integrating the top-down design of PDMS device with the bottom-up design of MT properties. Demonstration of MT sorting by.

Fig. 7 LSH database and similarity search example.

Fig. 2 Self-organization into artificial mature blood vessels.

CD169+ macrophages mediate the transport of bacteria to T cell zones by trans-infecting CD8α+ DCs. CD169+ macrophages mediate the transport of bacteria.

Fig. 1 Characterization of Suv420h dKO mice.

Fig. 4 Rotation of nuclei in oocytes in the primordial follicles.

Fig. 4 Super-resolution live imaging of calcium containing vesicle transports via lysosomes. Super-resolution live imaging of calcium containing vesicle.

Fig. 1 NP-free Ch-CNC droplets.

Interactive morphogenesis in Ch-CNC droplets laden with magnetic NPs

Fig. 1 Device structure, typical output performance, and cytocompatibility of BD-TENG. Device structure, typical output performance, and cytocompatibility.

Fig. 4 The performance of quasi–solid state Na-CO2 batteries with rGO-Na anodes. The performance of quasi–solid state Na-CO2 batteries with rGO-Na anodes.

Fig. 2 Images of complex structures formed via sequential folding.

Fig. 4 Organ-scale FRESH 3D bioprinting of tri-leaflet heart valve, multiscale vasculature, and neonatal-scale human heart. Organ-scale FRESH 3D bioprinting.

Fig. 5 Recruitment of a downstream polarity complex triggered by the MT arrival. Recruitment of a downstream polarity complex triggered by the MT arrival.

Fig. 3 Transport characterization of dry-assembled devices.

Fig. 3 C9ORF72 interacts with SMCR8 in a DENN domain–dependent manner.

Fig. 2 IRF8 is expressed in CD68+ macrophages after SCI.

Fig. 1 Schematic view and characterizations of FGT/Pt bilayer.

Fig. 3 The bacteria loading capacity and biocompatibility of GA/Pt.

Fig. 1 A hollow polymer fiber filled with solid gallium creates a tough metamaterial core-shell fiber. A hollow polymer fiber filled with solid gallium.

CLIC1 is upregulated in invadopodia of fibrin-embedded tumor and endothelial cells. CLIC1 is upregulated in invadopodia of fibrin-embedded tumor and endothelial.

Fig. 5 C9orf72 knockdown disrupts autophagy induction.

IFN treatment of human midgestation villous explants induces syncytial knot formation. IFN treatment of human midgestation villous explants induces syncytial.

Fig. 2 XRD, SEM-EDX, and three-dimensional optical characterization.

Interpreted seismic reflection image across reactivated fracture zones

Fig. 6 MD simulations of assembled binary supraballs.

Fig. 1 Development of epidermal scales during reptilian embryogenesis.

Fig. 5 Distributions of cell nuclear area values and internuclear distances in the breast tumor specimens (Figs. 3 and 4), where bin interval = 8 and n.

Fig. 5 Reconstitution of the dormant state using fetal ovaries.

Volume 115, Issue 4, Pages (October 1998)

Fig. 1 Schematic structure of a fluorescently labeled eGLP1-conjugated MALAT1 ASO and internalization of fluorescent eGLP1 and eGLP1-MALAT1-ASO. Schematic.

Fig. 10 Map of light pollution’s visual impact on the night sky.

Fig. 3 MCA-mediated neutrophil recruitment accelerates bacterial clearance in the skin. MCA-mediated neutrophil recruitment accelerates bacterial clearance.

Fig. 4 In situ mapping of human patient breast cancer and stroma.

Fig. 1 FETs constructed from densely packed semiconducting CNT arrays.

Fig. 4 Acoustophoretic printing of food, optical, biological, and electrically conductive materials. Acoustophoretic printing of food, optical, biological,

The neuropod cells. The neuropod cells. (Top left) Neuropod cells synapse with sensory neurons in the small intestine, as shown in a confocal microscopy.

Fig. 1 Sacrificial writing into functional tissue (SWIFT).

Fig. 2 Reduced dendritic complexity of neurons in the prelimbic layer of the mPFC 8 weeks after HZE particle irradiation. Reduced dendritic complexity.

Fig. 2 Printed three-axis acceleration sensor.

Presentation transcript:

Fig. 4 FRESH printed scaffolds with complex internal and external architectures based on 3D imaging data from whole organs. FRESH printed scaffolds with complex internal and external architectures based on 3D imaging data from whole organs. (A) A dark-field image of an explanted embryonic chick heart. (B) A 3D image of the 5-day-old embryonic chick heart stained for fibronectin (green), nuclei (blue), and F-actin (red) and imaged with a confocal microscope. (C) A cross section of the 3D CAD model of the embryonic heart with complex internal trabeculation based on the confocal imaging data. (D) A cross section of the 3D printed heart in fluorescent alginate (green) showing recreation of the internal trabecular structure from the CAD model. The heart has been scaled up by a factor of 10 to match the resolution of the printer. (E) A dark-field image of the 3D printed heart with internal structure visible through the translucent heart wall. (F) A 3D rendering of a human brain from MRI data processed for FRESH printing. (G) A zoomed-in view of the 3D brain model showing the complex, external architecture of the white matter folds. (H) A lateral view of the brain 3D printed in alginate showing major anatomical features including the cortex and cerebellum. The brain has been scaled down to ~3 mm in length to reduce printing time and test the resolution limits of the printer. (I) A top down view of the 3D printed brain with black dye dripped on top to help visualize the white matter folds printed in high fidelity. Scale bars, 1 mm (A and B) and 1 cm (D, E, H, and I). Thomas J. Hinton et al. Sci Adv 2015;1:e1500758 Copyright © 2015, The Authors