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Version STLThis is a .stl file of a left temporal bone ready for 3d printing. I have segmented a CT scan paying attention to all the important bony structures of the ear. In the .stl screenshots you can see the mastoid, malleus, incus, the bony canal of the facial nerve, the stylomastoid foramen Etc. I do this for my training and the idea is to perform a mastoidectomy just in my desktop i have printed my personal 3d plaster model (you can see in the screenshots) but i haven't the courage to destroy it whit the drill..... I hope that my work can be of help to anyone who wants to try to drill a faithful model of temporal bone at home or simply want to study the anatomy in a versatile 3d .stl Model Good Job Nicola Di Giuseppe M.D.
mattjohnson posted a blog entry in Matt Johnson's Biomedical 3D Printing BlogRecent developments in the field of three-dimensional (3D) medical printing and bioprinting can revolutionize the way doctors approach ear disorders. The technology, also known as additive printing, allows the user to deposit a desired material on a specific substrate in a pre-determined manner to create 3D prints with definitive shapes and sizes. Scientists and healthcare professionals are already relying on this technology to create surgical instruments, anatomical models, diagnostic tools, prosthetics and even body parts. These novel solutions are offering hope to more than 360 million men, women and children across the globe who suffer from some form of hearing loss. 3D Printing and Smart Phones Make for Easy and Affordable Diagnoses Recently, students of A&M Texas University’s chapter of Engineering World Health used a 3D printer to create LED ostoscope smartphone attachments that take pictures of the patients’ inner ears and help diagnose conditions contributing to hearing loss. Unlike traditional ostoscopes that cost hundreds of dollars, these smartphone attachments can be built for just $6.42. Doctors working in underprivileged areas of South Asia, Asia Pacific and Sub-Saharan Africa can depend on this imaging device for accurate diagnosis, prompt treatment and effective prognosis. 3D Printed Hearing Aids Ontenna, a simple hairclip with a built-in hearing aid, is another glowing example of the way 3D printing technology is impacting Otology. The 3D printed device picks up sounds between 30 and 90 decibles and translates them into 256 different vibrations and light patterns that allow the wearer to actually feel and see the sound. Ontenna was developed by Tatsuya Honda, a researcher and sign language interpreter, who worked closely with the deaf community and understood the drawbacks of traditional hearing aids. The device is currently in the testing phase and may soon be available for commercial use. 3D Printing and Ear Prosthetics In another pioneering attempt, physicians at Royal Hospital for Sick Children in Edinburgh, Scotland, under the supervision of Dr. Ken Stewart, adopted the 3D printing technology to treat microtia, a congenital disorder characterized by underdeveloped ears. Traditionally, children with this condition were required to lay down in an MRI machine for a significant period of time while the doctors obtained a 2D tracing of the normal ear. Understandably, most children were overwhelmed by the process and became fearful of it. Doctors in Edinburgh are now using a 3D scanner to obtain the exact dimensions of the child’s ear. A 3D printer then creates a replica of the organ, which is sterilized and used during the carving process. Dr. Stewart is also working with Edinburgh University’s Centre for Regenerative Medicine and Chemistry Department to bioprint an ear using the patient’s own stem cells and is very excited about the potential of 3D printing in managing hearing loss. 3D Printing the Ear A study published in the October, 2015, edition of the journal Nature Biotechnology revealed that researchers have succeeded in printing human-sized ears with the help of the Integrated Tissue and Organ Printing System (ITOP) and have implanted them into mice. The implanted organs retained their shape over the next two months and formed blood vessels and cartilages. Success of ITOP in animal models is a big step in the right direction as it will allow doctors to print complex ear implants that are stable and functional. Most people take their sense of hearing for granted. However, many conditions ranging from infections and injuries to fluid problems can impact it. Physicians and patients are looking for treatments that will help overcome deficiencies associated with existing modalities, and 3D printing technology is helping them do just that. Sources: http://thebridge.jp/en/2015/08/ontenna-lets-you-hear-sounds-through-your-hair http://www.bustle.com/articles/142312-3d-printed-ear-jaw-muscle-implants-are-revolutionizing-medical-technology