3D Printing in Medical Sector
Segmentation
Segmentation is the process of converting DICOM images obtained from CT or MRI scans into a high-resolution, virtual 3D model.
Virtual 3D models can be utilized to gain deeper insights into any deformities, plan complex surgical procedures, and create 3D-printed models for improved understanding and communication.
By leveraging advanced computer algorithms and machine learning techniques, segmentation enables medical professionals to extract and isolate regions of interest from complex and noisy medical images.
Anatomical Models Prinitng
By providing a tangible and highly realistic representation of the patient's anatomy, 3D-printed anatomical models allow improved visualization, greater accuracy, and enhanced communication between medical professionals and their patients.
3D-printed anatomical models are used for surgical planning and training, allowing surgeons to simulate surgical procedures and test various approaches in a low-risk environment.
Additionally, these models can be leveraged for research purposes, such as studying disease progression or testing new treatments.
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Virtual Surgical Planing
VSP enables medical professionals to plan and simulate the surgery, including the steps, selection of optimal osteotomy sites, implant size, graft size, and materials needed, which allows them to predict the outcomes of the surgery.
Using VSP, surgeons can visualize the biomechanical angles, lengths, and symmetry of the patient's anatomy, and fine-tune every aspect of the plan before the procedure begins.
By utilizing VSP, surgeons can reduce the risk of complications, shorten recovery times, and achieve better patient outcomes.
Surgical Jig Design
A Surgical Guide is a highly precise patient-specific 3D-printed medical device used to assist the surgeon during the surgical procedure.
This guide acts as a jig that replicates the surgical outcome that was planned virtually, enabling the surgeon to make highly precise cuts in the patient's anatomy, dramatically reducing the operating time, and leading to better patient outcomes and faster recovery times.
These surgical guides are biocompatible and are designed to match the specific patient's anatomy, taking into consideration the intended deformity correction and implant that will be used during the procedure. The guide features precise slots and holes aligned with the osteotomy and predrilling locations required for the chosen implant.
Custom Implants
Custom-made 3D-printed implants are specifically designed to match the unique anatomy of each patient and provide maximum bone restoration and aesthetic appeal while replicating critical structures with remarkable accuracy.
These implants are engineered with improved surface quality, mechanical properties, and dimensional and symmetrical accuracy. The trabecular structure of the implants allows for enhanced osseointegration and bone ingrowth, leading to better fixation and movement restoration.
They are lightweight and offer a perfect fit, which enables easy positioning during surgery and reduces operating time.
Prosthetics and Orthosis
3D-printed prosthetics and orthoses are precisely tailored to each patient's individual needs.
3D-printed prosthetics and orthoses are typically lighter and more comfortable than their traditionally manufactured counterparts, making them easier for patients to wear and use. They also allow for greater customization in terms of size, shape, and design, which can help patients to achieve a more natural and functional appearance.
Bioprinting
Bioprinting is an exciting and rapidly growing field that has the potential to revolutionize the field of medicine, offering a range of possibilities for creating replacement tissues and organs for patients in need.
Using specialized 3D printers and bio-inks, researchers can create complex 3D structures that contain living cells and biological materials.
These structures can then be used to repair or replace damaged tissues and organs, or to test the safety and efficacy of new drugs and treatments.
Bioprinting is still a relatively new technology, and researchers are continuing to explore new ways to use it to benefit patients. However, the potential for bioprinting to transform the field of medicine is clear, and it represents an exciting frontier in medical research and innovation.
Medical Animations
Medical animations and renders are powerful tools for teaching and patient education. These digital visualizations help medical professionals explain complex medical concepts, procedures, and conditions to patients, students, and other healthcare professionals.
They can also be used to show the steps of medical procedures, such as surgeries or treatments, helping patients and healthcare professionals to better understand what to expect.
One of the key benefits of medical animations and renders is their ability to simplify complex medical information and make it more accessible to a wider audience. They can also be used to provide visual aids for patients who may have difficulty understanding medical jargon or complex diagrams.
