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.
Search for: regenerative medicine
In a world premiere, a team of researchers has developed a magnetic 3D printed microscopic robot that can carry cells to precise locations in live animals.
Robotic device acts as a cane-like mobile assistant to provide light-touch to help the elderly and others with impaired mobility.
A team of engineers has developed a prototype bandage designed to actively monitor the condition of chronic wounds.
A convection-enhanced macroencapsulation device offers the potential of faster and more effective treatment for people with type 1 diabetes.
The Scar Free Foundation has launched a research programme that aims to revolutionise surgeons’ ability to reconstruct nose and ear cartilage in patients affected by facial difference.
Researchers have developed a robotic neck brace that may help doctors analyze the impact of cancer treatments on the neck mobility of patients and guide their recovery.
Clinicians are using patient-specific tumor 'organoid' models as a preclinical companion platform to better evaluate immunotherapy treatment for appendiceal cancer.
AI-driven healthcare has the potential to transform medical decision-making and treatment, but these algorithms must be thoroughly tested and continuously monitored to avoid unintended consequences to patients.
Researchers have experimentally demonstrated a novel cancer diagnosis technique based on the scattering of circularly polarized light.
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.
Researchers have fabricated 3D scaffold implants containing antibiotics at high temperatures. These scaffolds support bone regeneration and manage the bone infections.
Researchers have shown that lab-created heart valves implanted in young lambs for a year were capable of growth within the recipient.
Researchers have developed an injectable hydrogel that could help repair and prevent further damage to the heart muscle after a heart attack.
Researchers have used lasers and molecular tethers to create perfectly patterned platforms for tissue engineering.
Reseachers have developed robotic Trunk Support Trainer (TruST) that helps children with CP to sit more stably.
Researchers mechanically reprocess silk into a biologically compatible component of bioinks that improves the structural fidelity of 3D-printed hydrogels containing cells for use in drug development and regrowing lost or damaged body
Radiator-like fluid systems adjust the genetic wiring inside human liver cells in preliminary work toward artificial organ-tissue engineering.
Scientists have developed a bioelectronic system driven by a machine learning algorithm that can shift the membrane voltage in living cells and maintain it at a set point for 10 hours.
New muscle has successfully been created in mice using a minimally invasive technique dubbed ‘intravital 3D bioprinting’.
RoSE is first device to measure 3D stiffness of human torso, could lead to new treatments for children with spine deformities such as idiopathic scoliosis and kyphosis.
In order for a COVID-19 vaccine and antiviral drugs to be developed, scientists first need to understand why this virus spreads so easily and quickly, and why it invades our bodies with seemingly little resistance from our immune system.
Researchers used a skin cream infused with microscopic particles, named STAR particles, for therapy of Skin diseases
Scientists have improved upon the bioprinting technique they developed to engineer skeletal muscle as a potential therapy for replacing diseased or damaged muscle tissue.
For the first time, researchers managed to make intact human organs transparent. Using microscopic imaging they could revealed underlying complex structures of the see-through organs at the cellular level.
Engineers have developed a robotic device that can be used to assist and train people with SCIs to sit more stably by improving their trunk control.
A comfortable brace incorporates both sensors and actuators to restore roughly 70% of the active range of motion.
In a new study, researchers have demonstrated a novel and non-invasive way to manipulate cells through microrobotics.