Jove
Visualize
Contact Us
JoVE
x logofacebook logolinkedin logoyoutube logo
ABOUT JoVE
OverviewLeadershipBlogJoVE Help Center
AUTHORS
Publishing ProcessEditorial BoardScope & PoliciesPeer ReviewFAQSubmit
LIBRARIANS
TestimonialsSubscriptionsAccessResourcesLibrary Advisory BoardFAQ
RESEARCH
JoVE JournalMethods CollectionsJoVE Encyclopedia of ExperimentsArchive
EDUCATION
JoVE CoreJoVE BusinessJoVE Science EducationJoVE Lab ManualFaculty Resource CenterFaculty Site
Terms & Conditions of Use
Privacy Policy
Policies

Related Concept Videos

Imaging Studies VII: Vascular Imaging01:19

Imaging Studies VII: Vascular Imaging

320
DefinitionRenal angiography, also known as renal arteriography, is an imaging technique used to obtain a comprehensive view of blood flow and the vascular structure of blood vessels in the kidneys and surrounding areas.PurposeRenal angiography detects blood vessel abnormalities in the kidneys, such as aneurysms, stenosis, thrombosis, vascular tumors, and renal artery stenosis. It evaluates kidney function and guides interventional treatments like angioplasty or stent placement.Pre-Procedure...
320
Imaging Studies IV: Magnetic Resonance Imaging01:27

Imaging Studies IV: Magnetic Resonance Imaging

230
Introduction:Magnetic Resonance Imaging, or MRI, can include a specialized imaging technique of the urinary system known as Magnetic Resonance Urography (MRU). This radiation-free technique uses strong magnetic fields and radio waves to produce detailed images with the help of a computer. MRU is particularly effective for visualizing fluid-filled structures like the kidneys, ureters, and bladder.Applications of MRI in the Genitourinary SystemKidneys and Ureters: MRI detects tumors, cysts,...
230
X-ray Imaging01:24

X-ray Imaging

9.9K
German physicist Wilhelm Röntgen (1845–1923) was experimenting with electrical current when he discovered that a mysterious and invisible "ray" would pass through his flesh but leave an outline of his bones on a screen coated with a metal compound. In 1895, Röntgen made the first durable record of the internal parts of a living human: an "X-ray" image (as it came to be called) of his wife’s hand. Scientists worldwide quickly began their own experiments with...
9.9K
Brain Imaging01:14

Brain Imaging

681
Brain imaging technologies provide critical insights into both the structure and function of the human brain, enabling medical professionals and researchers to diagnose, study, and treat neurological disorders or psychiatric disorders more effectively.
These technologies include computerized axial tomography (CAT or CT scans), positron-emission tomography (PET scans),  magnetic resonance imaging (MRI),  functional magnetic resonance imaging (fMRI), and Transcranial Magnetic...
681
Magnetic Resonance Imaging01:24

Magnetic Resonance Imaging

9.1K
Magnetic resonance imaging (MRI) is a noninvasive medical imaging technique based on a phenomenon of nuclear physics discovered in the 1930s, in which matter exposed to magnetic fields and radio waves was found to emit radio signals. In 1970, a physician and researcher named Raymond Damadian noticed that malignant (cancerous) tissue gave off different signals than normal body tissue. He applied for a patent for the first MRI scanning device in clinical use by the early 1980s. The early MRI...
9.1K
Imaging Studies II: Ultrasonography01:24

Imaging Studies II: Ultrasonography

390
IntroductionUltrasonography, or renal ultrasound, is a noninvasive medical imaging technique that uses high-frequency sound waves to visualize the kidneys, ureters, bladder, and surrounding tissues.Indications for Urinary System UltrasonographyUrinary system ultrasonography is indicated in various clinical scenarios, such as:Kidney Stones (Urolithiasis): To detect and monitor the size and presence of kidney or urinary tract stones.Hydronephrosis: To assess the dilation of the renal pelvis and...
390

You might also read

Related Articles

Articles linked to this work by shared authors, journal, and citation graph.

Sort by
Same author

Hybrid bioprinting of hierarchical vascular networks at capillary-scale resolution.

Nature chemical engineering·2026
Same author

A 3D-bioprinted head and neck cancer model for drug screening.

Biomedical materials (Bristol, England)·2026
Same author

Reprogramming macrophage mechanosensation via TRPV4 modulating mechano-immunotherapy controls fibrotic encapsulation of biomaterial implants.

Bioactive materials·2026
Same author

MCC950-loaded silk microgel-hydrogel composite scaffolds effectively modulate inflammation for improving tissue interaction and remodeling.

Acta biomaterialia·2026
Same author

4D-printed adaptive hydrogel tissue expanders for ear and breast reconstruction.

Nature biomedical engineering·2026
Same author

Additive Manufacturing of Ordered Polymer Nanostructures.

Advanced materials (Deerfield Beach, Fla.)·2026

Related Experiment Video

Updated: Jan 23, 2026

Design and Validation of a Volumetric-extrusion Bioprinter for Bioprinting of Soluble Basement Membrane Extract for Translational Research
08:27

Design and Validation of a Volumetric-extrusion Bioprinter for Bioprinting of Soluble Basement Membrane Extract for Translational Research

Published on: March 28, 2025

716

Image-guided volumetric bioprinting.

Thomas M Robinson1, Yu Shrike Zhang2, Khoon S Lim1

  • 1School of Medical Sciences, Faculty of Medicine and Health, University of Sydney, Camperdown, Sydney, New South Wales 2006, Australia.

Trends in Biotechnology
|January 21, 2026
PubMed
Summary
This summary is machine-generated.

Image-guided volumetric bioprinting enables adaptive fabrication of complex tissue engineering structures. This new workflow uses computer vision to create vascular networks that improve cell functionality within hydrogels.

Keywords:
adaptivebiofabricationvolumetric

More Related Videos

Bioprinting of Cartilage and Skin Tissue Analogs Utilizing a Novel Passive Mixing Unit Technique for Bioink Precellularization
09:03

Bioprinting of Cartilage and Skin Tissue Analogs Utilizing a Novel Passive Mixing Unit Technique for Bioink Precellularization

Published on: January 3, 2018

13.9K
Lesion Explorer: A Video-guided, Standardized Protocol for Accurate and Reliable MRI-derived Volumetrics in Alzheimer's Disease and Normal Elderly
12:50

Lesion Explorer: A Video-guided, Standardized Protocol for Accurate and Reliable MRI-derived Volumetrics in Alzheimer's Disease and Normal Elderly

Published on: April 14, 2014

40.8K

Related Experiment Videos

Last Updated: Jan 23, 2026

Design and Validation of a Volumetric-extrusion Bioprinter for Bioprinting of Soluble Basement Membrane Extract for Translational Research
08:27

Design and Validation of a Volumetric-extrusion Bioprinter for Bioprinting of Soluble Basement Membrane Extract for Translational Research

Published on: March 28, 2025

716
Bioprinting of Cartilage and Skin Tissue Analogs Utilizing a Novel Passive Mixing Unit Technique for Bioink Precellularization
09:03

Bioprinting of Cartilage and Skin Tissue Analogs Utilizing a Novel Passive Mixing Unit Technique for Bioink Precellularization

Published on: January 3, 2018

13.9K
Lesion Explorer: A Video-guided, Standardized Protocol for Accurate and Reliable MRI-derived Volumetrics in Alzheimer's Disease and Normal Elderly
12:50

Lesion Explorer: A Video-guided, Standardized Protocol for Accurate and Reliable MRI-derived Volumetrics in Alzheimer's Disease and Normal Elderly

Published on: April 14, 2014

40.8K

Area of Science:

  • Bioprinting
  • Tissue Engineering
  • Biomaterials

Background:

  • Volumetric bioprinting offers advanced fabrication capabilities for tissue engineering.
  • Adaptive strategies are needed to integrate living cells and vascular networks into engineered tissues.
  • Current methods face challenges in creating complex, functional cellular architectures.

Purpose of the Study:

  • To introduce a novel image-guided volumetric bioprinting workflow.
  • To enable adaptive fabrication of complex 3D structures for tissue engineering.
  • To improve the functionality of living cells within engineered constructs.

Main Methods:

  • Development of Generative, Adaptive, Context-Aware 3D Printing (GACAP) workflow.
  • Integration of computer vision for automated network generation.
  • Bioprinting of vascular-like networks within hydrogels containing living cells.

Main Results:

  • Successful generation of functional, vascular-like networks.
  • Networks conformed to the presence and distribution of living cells.
  • Demonstrated improvement in cellular functionality within the bioprinted constructs.

Conclusions:

  • Image-guided volumetric bioprinting facilitates adaptive fabrication.
  • GACAP workflow enhances the integration and functionality of cells in tissue engineering.
  • This approach holds promise for creating more sophisticated and functional engineered tissues.