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an orthopedic surgeon at Rehasport Clinic
FIFA Medical Centre of Excellence
Ortopeda specjalizujący się w leczeniu chorób i uszkodzeń kończyny dolnej, współautor powstania nowoczesnych technik operacyjnych, m.in. regeneracji chrząstki stawowej oraz łąkotki (AMIC).
Członek wielu krajowych i międzynarodowych towarzystw medycznych, Dyrektor Generalny Szkoły Artroskopii Smith+Nephew SNACE. Jest absolwentem Akademii Medycznej
w Poznaniu, gdzie obronił doktorat, później uzyskał drugi stopień specjalizacji, aż wreszcie stopień naukowy doktora habilitacji.
Jest międzynarodowym trenerem technik operacyjnych artroskopii stawu kolanowego i biodrowego.
Jedna z wiodących klinik ortopedycznych w Polsce,
mająca swoje siedziby w Warszawie, Poznaniu, Gdańsku i Koninie, a także ponad sto współpracujących z nią Licencjonowanych Ośrodków Rehabilitacyjnych w całej Polsce.
Członek wielu krajowych i międzynarodowych towarzystw medycznych, Dyrektor Generalny Szkoły Artroskopii Smith+Nephew SNACE. Jest absolwentem Akademii Medycznej
w Poznaniu, gdzie obronił doktorat, później uzyskał drugi stopień specjalizacji, aż wreszcie stopień naukowy doktora habilitacji.
Jest międzynarodowym trenerem technik operacyjnych artroskopii stawu kolanowego i biodrowego.
Ever wanted to actually grab the patient bones in you PACS? All your dicom CT scans can now mimic actual objects in real space.
RSQ HOLO works amazingly through Microsoft HoloLens goggles. Sounds like magic but technically it's just a PC on your head.
You can take your holograms anywhere since technically they exist only in front of your eyes. More precisely, they are light projected onto your retina.
Finding individual elements, collecting all of them and combining together allows us to see this image basically without having to touch anything, as the hologram in space is absolutely sterile.
Another thing I’d consider an advantage is arthroscopy, especially arthroscopy of the elbow, where, in the case of degenerative changes, there are a lot of osteophytes that we have to see in three dimensions and get to them. Then in the visible image, where arthroscopy of the elbow is an arthroscopy where relatively little is visible and some things have to be imagined, it is like an extension of our imagination, and we have this image right in front of us, literally above our operative bed, so we do not have to turn our head.
Another promising application, perhaps even the greatest, is the correction of bone settings for example, after badly healed fractures, such as a defective healing of fracture of the distal part of the humerus, where by using appropriate wedges, we can carefully monitor the location and angle of bone cuts.
This precision will help us and those who deal with this type of reconstructive surgery and surgery that requires great detail and a lot of specialization. Most of my colleagues who have dealt with this type of system are absolutely delighted, because it can change their procedures.
This applies to, for example, minor fractures, multi-fragment fractures, fractures of the distal parts of the articular bones, such as hip and knee arthroscopy; we are already starting to navigate with the holographic system in the arthroplasty of the shoulder joint, which is one of the most difficult arthroplasty procedures.
My colleagues, who also use it, literally learned it shortly before the surgery. Of course, the more you use it, the more nuances become apparent which also teach you new things. As well as the fact that it can be later used to record certain things, to stream this image to, for example, another colleague someplace else or to other learners, so this system gives a lot of possibilities. However, the basics I talked about are very easy to learn and are very intuitive.
