Printing patient specific 3D models is an emerging practice in the healthcare industry that provides doctors with an enhanced understanding of their patients' anatomy and physiology. The technology has the potential to help surgeons prepare for complex surgeries, reduce surgical time, and improve patient outcomes.
Creating a patient specific model requires a combination of software and printing tools. This includes processing the scans, converting them into 3D files, and uploading them to a printer. The process can be challenging, but it is essential for high quality 3D models.
Surgeons use these models to get their eyes and hands on the organ or body part they are about to operate on, which helps them plan out the surgery and ensure the correct procedures are performed. This can result in a decrease in operating time and save the hospital money. Know about this here!
These models can also be used for patient education, including helping patients understand their condition and the procedures involved in surgery. Additionally, they can help medical students, residents, and fellows learn surgical skills by practicing simulation-based training outside of the operating room environment. Be sure to learn more here!
The gynecology field is one that is in need of innovative solutions that will help doctors better prepare for surgical cases and increase surgical efficiency. This is particularly true with endometriotic conditions, such as uterine cancer. The need for a clear understanding of the disease, its treatment and risk factors, along with an awareness of possible complications, is crucial to successful surgical outcome.
In a recent study, researchers demonstrated the utility of patient-specific 3D printed models for gynecological surgical planning and training in five patients with uterine endometriosis. The study showed that the models helped patients to gain a better understanding of their disease, the surgical procedure, and the risk of complications.
Surgeons can also make use of patient-specific models for preoperative planning and surgical simulations. This allows them to experiment with different techniques and equipment before stepping into the operating theatre, which can cut down on the time spent in the surgery. It also means that they can reduce the number of complications that occur during surgery, which will improve their overall clinical performance and results.
Doctors can also use a system like Media2DICOM to convert videos or 3D scans into standardized DICOM data for access by physicians. This enables image technicians to easily import the models into their healthcare facility's PACS and provide patients with more detailed information about their anatomy and physiology.
This system is designed to work with all types of 3D scanners, from traditional MRI and CT systems to those that utilize newer technologies. The software allows the images to be filtered, segmented, and transformed into 3D visualizations. It also provides contours and labels for each region of interest.
The end result is a high-fidelity anatomical model that accurately mimics the patient's anatomy. This can be especially useful in reconstructive and trauma surgery, where the surgeon is trying to re-create the exact shape of an organ or limb that was damaged during a previous surgery. Learn more about surgey at https://en.wikipedia.org/wiki/Neurosurgical_anesthesia.