Researchers have developed a new bioprinting technique based on voxels.
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The material can take any possible shape and could be used in robotics and biotechnology.
Egidijus Pelanis, a medical doctor at Oslo University Hospital, explains how extended realities is applied in the operating room.
Researchers have used machine learning to help reconstruct three-dimensional micro-CT images of fibrous materials.
Researchers at Tel Aviv University have printed an entire active and viable glioblastoma tumor using a 3D printer.
A team of researchers at Washington University School of Medicine have developed a deep learning model that is capable of classifying a brain tumor as one of six common types using a single 3D MRI scan.
Marc Knebel, head of Medical Systems at Evonik, explains the benefits and applications of the new high-performance polymer VESTAKEEP Care M40 3DF.
Clinicians are using patient-specific tumor 'organoid' models as a preclinical companion platform to better evaluate immunotherapy treatment for appendiceal cancer.
The team of the Dynamic HIPS are working on a hip replacement simulator that will help future surgeons to practice the intervention.
Researchers have developed a new process for producing movable, self-adjusting materials systems with standard 3D-printers.
Researchers aim to speed up developing drugs against brain diseases through cutting-edge technology. They are generating an innovative technology platform based on high-density microelectrode arrays and 3D networks of human neurons.
New research could help surgeons perform liver resections with greater accuracy and deliver improved patient outcomes.
Researchers have created a novel 3D printing workflow that allows cardiologists to evaluate how different valve sizes will interact with each patient's unique anatomy, before the medical procedure is actually performed.
Researchers have used 3D bioprinting technology to create custom-shaped cartilage. They aim to make it easier for surgeons to safely restore the features of skin cancer patients living with nasal cartilage defects after surgery.
To reduce tissue injury side effects from radiation therapy, researchers have developed 3D-printed gastrointestinal radioprotective devices that can be generated from patient CT scans.
The combination of a 2Photon 3D-printer with an innovative hydrogel-based bioink allows the direct printing of 3D structures containing living cells at both the meso- and microscale.
EPFL spin-off Readily3D has developed a novel system that can print biological tissue in just 30 seconds.
Researchers are developing 3D technologies for surgeons. The aids for surgery planning are particularly advanced.
Researchers have designed a new bioink which allows small human-sized airways to be 3D bioprinted with the help of patient cells for the first time.
In 2032, a man lies critically injured on a remote road following a car accident. His life is in the balance, but data visualization, remote robotics, biofabrication and virtual care will combine to give him the best possible chance of survival.
Deep learning-based system enables dermatologist-level identification of suspicious skin lesions from smartphone photos, allowing better screening.
Engineers have developed a new method that uses light to improve 3D printing speed and precision while also, in combination with a high-precision robot arm, providing the freedom to move, rotate, or dilate each layer as the structure is being built.
Researchers have constructed a 3D vision-guided artificial skin that enables tactile sensing with high performance, opening doors to innumerable applications in medicine.
Computer scientists use TACC systems to generate synthetic objects for robot training.
A new website allows teachers and students to explore concepts from chemistry and biology by manipulating virtual molecules in augmented reality.
Scientists have demonstrated a VR technique which should help in developing drugs against the SARS-CoV-2 virus – and enable researchers to share models and collaborate in new ways.
Researchers have adapted a new class of materials for their groundbreaking volumetric 3D printing method that produces objects nearly instantly, greatly expanding the range of material properties achievable with the technique.
Researchers have demonstrated that their technique can stop the catheter at the right target and identify the source type with a 95.25 percent success rate.
Researchers have developed a robotic exoskeleton that improves the lives of people with limited or no ability to move due to neurological and/or physiological disorders.
Radiator-like fluid systems adjust the genetic wiring inside human liver cells in preliminary work toward artificial organ-tissue engineering.
A dose of artificial intelligence can speed the development of 3D-printed bioscaffolds that help injuries heal.
Linking the human brain to a computer is usually only seen in science fiction, but now scientists have harnessed the power of 3D printing to bring the technology one step closer to reality.
Researchers at TU Vienna have created an artificial placenta-on-a-chip microfluidic device, using a high-resolution 3D printing process.
Scientists have paired 3D-printed, living human brain vasculature with advanced computational flow simulations to better understand tumor cell attachment to blood vessels.
Scientists and collaborators are using machine learning to address two key barriers to industrialization of two-photon lithography.
Engineers are developing a 3D printed artificial blood vessel that allows doctors and patients to keep tabs on its health remotely.
Researchers have developed a MR visualisation platform which projects multiple imaging modalities to assist intraoperative surgical guidance.
New muscle has successfully been created in mice using a minimally invasive technique dubbed ‘intravital 3D bioprinting’.
A deep learning powered single-strained electronic skin sensor can capture human motion from a distance.
Engineers are developing a massive fluid dynamics simulator that can model blood flow through the full human arterial system at subcellular resolution.
An anaesthesia team used 3D printing and virtual reality to produce an exact model of the airway of a 7-year-old girl in order to prepare properly for an operation to remove part of her lung.
Researchers have developed a new model that accurately and automatically shows the exact location of mandibular canals.
Penn State engineers say computational power is key to technology for smart bandages, health tattoos and artificial organs.
Researchers demonstrated a methodology that combines the bioprinting and imaging of glioblastoma cells in a way that more closely models what happens inside the human body.
Scientists have improved upon the bioprinting technique they developed to engineer skeletal muscle as a potential therapy for replacing diseased or damaged muscle tissue.
Rutgers University have devised a way to integrate microneedles with backward facing barbs, so that microneedle arrays can stay in place as long as needed.
Researchers have developed a novel methodology to provide non-invasive analysis of meniscal implants.
Researchers have developed a technique to improve the characteristics of engineered tissues by using ultrasound to align living cells during the biofabrication process.
Researchers have developed a new design method that shows promise in enabling the efficient design and fabrication of soft robots using a 3D printer.
Researchers have devised a technique that extends the capabilities of fluorescence microscopy, which allows scientists to precisely label parts of living cells and tissue with dyes that glow under special lighting.
Researchers have developed a way to 3D print custom microswimmers that can transport drugs and nanotherapeutic agents, as well as potentially manipulate tissue directly inside the body.
Scientists have made a decisive contribution to improving complex surgical training by developing a very realistic prostate phantom.
An algorithm did better than experts radiologists at finding tiny brain hemorrhages in head scans — an advance that one day may help doctors treat patients with strokes.
A scientist is working to develop miniature implantable medical devices that sense and communicate wirelessly via sound waves.
Scientists have found the perfect geometry: on a newly developed 3D silicone lattice, human stem cells will grow and behave in the same way as they do inside the human body.
A new 3D printed prosthetic hand can learn the wearers' movement patterns to help amputee patients perform daily tasks.
Researchers have announced a collaboration to 3D bioprint stem-cell tissue that could one day be used to treat end-stage kidney disease.
Researchers announce critical advances in the use of 3D-printed coronary phantoms with diagnostic software, further developing a non-invasive diagnostic method for Coronary Artery Disease risk assessment.
Scientists are using 3D technology to help rebuild the faces of cancer patients, those hurt in accidents and people born with complex facial deformities.
At ECR 2019, researchers talked about the practical applications of mixed realities in medical education and training as well as preprocedural planning and visualization during a surgery.
Thanks to developments in 3D bioprinting, the UT researchers could create a miniature brain model representing the delicate tissue around the tumor, including the macrophages.
Researchers at the University of Stuttgart have built an exoskeleton with which the gripping ability of a paralyzed hand can be restored.
Medical software that overlays tumour information from MRI scans onto ultrasound images can help guide surgeons conducting biopsies and improve prostate cancer detection.
Orthopaedic surgeons can now get their hands on the bones of patients before they reach the operating table – with the help of 3D printing.
AR offers a new platform to help physicians better visualize complex medical data, particularly before and during medical procedures.
Engineers have developed a 3D printing technique that allows for localized control of an object's firmness, opening up new biomedical avenues that could one day include artificial arteries and organ tissue.
Research project is aimed at improving therapeutic options for both rare and common diseases, including supporting methods to improve editing the human genome.
Mobile Brain/Body Imaging system combines virtual reality, brain monitoring, and motion capture technology for researchers to study neurological disorders.
Smart surgical glasses Caduceus use revolutionary technology that combines mixed reality with surgical navigation that allow surgeons to visualize a 3D model of a patient’s body during surgery in real time.
Engineers have created robust, highly flеxible, tattoo-like circuits for the usе in wearаble cоmputing.
University of Texas at Arlington patents headset that allows persons to point to objects of interest using their eyes.
A series of procedures have shown how surgeons can use computer-generated augmented reality imaging while operating on patients undergoing reconstructive lower limb surgery.
Students create 3d printed healthcare simulators for medical training.
3D printed device should help to train doctors and nurses in developing countries and low-resource areas to prevent and treat cervical cancer.
By combining high-tech 3D printing technology with kickball and pieces of chicken breast, surgeons have devised an innovative way to “rehearse” complex minimally invasive fetal surgeries.
Less expensive and more realistic 3D models of blood vessels may offer alternative to the commercial standard.