MUSTable

MECHANICS AND CONTROL

M.U.S.Table system, focuses on surgical applications of the lower limb and spinal surgery. As part of these applications, the integration of intraoperative imaging in a hybrid operating room will be pursued in order to reduce misplacements, the primary cause of re-intervention and prolonged patient stay, resulting in increased costs for the healthcare facility.

The operating table system developed under the project will meet the primary requirement of flexibility and compatibility, be adaptable to different surgical disciplines, and interface with pre-existing columns in the operating room.

Movement of the operating table will be carried out by electro-mechanical control in order to overcome the inherent limitations of electro-hydraulic systems. From an energy perspective, electromechanical actuators offer substantial savings because they consume only when at work. They also provide easier control in complex applications by providing accurate position and speed control and simple programmability of motion profiles.

MATERIALS

The enormous potential offered by composite materials will enable the partnership to substantially optimize the constituent components of the operating table system by exploiting the properties of the materials that will be analyzed in the context of the M.U.S.Table project. The ultimate goal will be to produce components and accessories that are not only nonconflicting with the windows of radiolucency necessary for the performance of modern orthopedic/traumatologic interventional procedures, but also lightweight, without having to pay the cost of insufficient mechanical strength.

Next, the possibility of introducing customized supports for specific surgical procedures in innovative radiolucent and 3D printable materials, such as high-performance plastic filaments containing carbon fibers that increase their stiffness and tensile strength, will be investigated. Indeed, the use of fiber-reinforced materials in additive manufacturing processes makes it possible to create lightweight and strong components characterized by even complex geometries. This, in addition to the great versatility of 3D printing would allow custom media to be generated.

Also in the context of innovative materials, great emphasis will be placed on the optimization of surgical floor covering materials (mats), which are major contributors to postoperative decubitus and necrosis. The combination of innovative synthetic viscoleastic/polymeric materials (e.g., EPDM, viscoelastic foams) will allow optimal distribution of patient load over as large a surface area as possible.

ELECTRONICS

The innovations envisaged by the M.U.S.Table project in terms of electronics can be divided into two major families relating, the first, to the control of the electromechanical system, and aimed at optimizing the handling and active safety of the operating table system; the second is directed at the user interface and data input/output.

Control system: the logic will be able to carry out new computational algorithms more quickly to meet greater operational needs for positioning and anti-collision control.

Data Input/Output: The planned architecture will allow greater control to and from the operating environment in terms of better connectivity with the surrounding world and improved user interaction.

SCIENTIFIC VALUE AND POTENTIAL ECONOMIC IMPACT OF THE PROJECT