Dipartimento di Ingegneria Meccanica e Industriale Department of Mechanical and Industrial Engineering The activities of Mechanical and Industrial Engineering Department. Director of DIMI Professor R. Faglia Mechanical and Industrial Engineering Dept DIMI Faculty of Engineering University of Brescia rodolfo.faglia@ing.unibs.it M.R.H. - Mechatronics based rehabilitation at home
M.R.H. - Mechatronics based Rehabilitation at Home Dipartimento di Ingegneria Meccanica e Industriale Mechatronics Lab Contact DIMI Director Rodolfo Faglia rodolfo.faglia@ing.unibs.it
M.R.H. - Mechatronics based Rehabilitation at Home Dipartimento di Ingegneria Meccanica e Industriale Bio-Mechatronics Rehabilitation Hand, lower-limb, Elbow Contact DIMI Director Rodolfo Faglia rodolfo.faglia@ing.unibs.it
M.R.H. - Mechatronics based Rehabilitation at Home Dipartimento di Ingegneria Meccanica e Industriale Vision System Handbike Contact Giovanni Legnani giovanni.legnani@ing.unibs.it
M.R.H. - Mechatronics based Rehabilitation at Home Dipartimento di Ingegneria Meccanica e Industriale Fluid-dynamics of aortic (mechanic and biological) valves prosthesis Contact PietroPoesio pietro.poesio@ing.unibs.it
M.R.H. - Mechatronics based Rehabilitation at Home Dipartimento di Ingegneria Meccanica e Industriale Finite elements modelling and analys of heart valves to optimise surgical operations, by simulating their functional and structural effects Contact: Giorgio Donzella Professor Email/tel giorgio.donzella@unibs.it +39 (0) 30 371 5553
M.R.H. - Mechatronics based Rehabilitation at Home Dipartimento di Ingegneria Meccanica e Industriale IREBID 2 International Research Exchange for Biomedical Devices Design and prototyping Contact Elisabetta Ceretti elisabetta.ceretti@unibs.it/ +39 (0) 303715583
Product Development Process Production Customer Needs & Market Trends? Health Sciences Manufacturing Process Design Product Design Product Concepts Engineering
Goal The expected result of the project is to develop solutions for the sector of biomedicine (new medical devices) and bioengineering listed in the proposal or others proposed by Doctors
Partners Americas European Union Rutgers Tec de Monterrey Brescia CTI Leiria Girona Mexico United States Brazil Spain Italy Portugal
Exchange conditions The European Commission supports the secondments of: Italian researchers going to Brazil, Mexico and USA researchers from Brazil, Mexico and USA to Italy Researchers are divided by EU in: ER (Experienced researcher): professors, researchers, PhD, students with a Bachelor degree and 4 years of research activity. ESR (Early Stage Researcher): students with a Bachelor and less than 4 years of research activity.
Activities Workshops Instructor: Partners with medicine schools Specialized medical doctors Lectures Attendance by all early stage researchers and other interested public Meetings Attendance by all experienced researchers Videoconference transmission to partner sites 12
Activities Joint Research Projects Focus: enabling technologies for biomedical device development Design Materials Prototyping Manufacturing Processes Exchange characteristics 2 to 3 partners Early stage researchers Length: 4 to 12 months Predefined outcomes in relation to the expert seminar findings 13
Joint Research Projects overview
Titanium Sheet for Biomedical Devices As well known, the biomedical compatibility of Titanium, makes it suitable for prosthesis. Moreover, the very high customization required by patients (till one single piece batch), makes ISF very suitable for plaque prosthesis such as in oral or skull implant.
IF for manufacturing Ti Sheet Geometry acquisition: CT STL file generation Tool path realization Final part Part production
Department of information Engineering SMART PROSTHESIS: DESIGN AND TEST OF AN AUTONOMOUS SENSOR FOR FORCE MEASUREMENTS IN HUMAN KNEE IMPLANTS. M.R.H. - Mechatronics based rehabilitation at home
INSTRUMENTED PROSTHESIS Department of Information Engineering Realization of an autonomous sensor to be placed inside the total knee prosthesis in order to measure the in-vivo forces applied to the insert itself. i Insertion of the circuit inside of tibial polyethylene insert. MAGNETS POLYETHYLENE INSERT Information on the load distribution of the joint directly from the insert. Support in the design of orthopedic implants. Useful during the post-operative rehabilitation. 125 khz 125 ANTENNA khz MAGNETORESISTORS M.R.H. - Mechatronics based rehabilitation at home
INSTRUMENTED PROSTHESIS Department of Information Engineering Power supply via an external magnetic field. An inductor connected to the reading device is positioned externally to the leg and creates an electromagnetic field that allows the sensor to self-sustaining. i Benefits It does not require batteries: maintenance and replacement batteries absent, environmentally friendly solution. READOUT UNIT M.R.H. - Mechatronics based rehabilitation at home Data transmission with wireless technology at 125 khz. Benefits No need for cables: reduced size and weight, minimal impact on pre-existing structure
INSTRUMENTED PROSTHESIS Department of Information Engineering Experimental Setup Force measurement up to 3000 N. M.R.H. - Mechatronics based rehabilitation at home FORCE [N] FORCE [N] 1100 1000 900 800 700 600 500 400 300 200 3000 2500 2000 1500 1000 500 0 Sinusoidal Excitation R_left Measured 0 60 120 180 240 300 TIME[s] Measured R_left R_right i Linear Excitation R_right R_center 0 100 200 300 400 500 TIMES [s]
WORKING PROGRESS Department of Information Engineering Redesign the mechanics of the tibial insert or change the type of transduction of the load applied to reduce the hysteresis due to the intrinsic viscoelastic properties of polyethylene. Develop an alternative method of supply the autonomous sensor, i such as systems based on the recovery of energy from mechanical vibrations. Prof. Emilio Sardini DII Faculty of Engineering University of Brescia emilio.sardini@ing.unibs.it +39 (0)30 3715922 Ing. Mauro Serpelloni DII Faculty of Engineering University of Brescia mauro.serpelloni@ing.unibs.it +39 (0)30 3715543 M.R.H. - Mechatronics based rehabilitation at home Acknowledge: Ing. Marco Gazzoli Ing. Vincenzo Luciano http://tech4health.ing.unibs.it
Examples of Activities on Mechatronics at the Dept. of Information Engineering - DII in collaboration with DIMI Vittorio Ferrari Faculty of Engineering University of Brescia vittorio.ferrari@ing.unibs.it M.R.H. - Mechatronics based rehabilitation at home
Sensors, Microsystems and MEMS Dipartimento di Ingegneria dell Informazione Screen-printing technology PCB technology MEMS technology M.R.H. - Mechatronics based rehabilitation at home
Piezoelectric Devices Dipartimento di Ingegneria dell Informazione for Sensing, Actuating and Vibration Control Vibration sensors for machine-tool monitoring In collaboration with Piezoelectric actuators for liquid nebulization Piezoelectric active vibration control 10 8 6 Oscillazione libera 4 Ampiezza (V) 2 0-2 -4-6 -8 Oscillazione controllata In collaboration with -10-0.2 0 0.2 0.4 0.6 0.8 1 Tempo (s) M.R.H. - Mechatronics based rehabilitation at home
Energy Harvesting Dipartimento di Ingegneria dell Informazione Environment Human body Energy Mechanical Thermal CONVERSION Electrical domain CONDITIONING LOAD Sensor with wireless output Electronic device /system Energy is converted from mechanical vibrations and motion, from thermal gradients and used to power battery-less sensors and electronic devices M.R.H. - Mechatronics based rehabilitation at home 500? µ m 500? µ m
Sensors for Fluidics and Microfluidics Sensor system for monitoring two-phase flows in pipes Dipartimento di Ingegneria dell Informazione Sensored microchannels for liquid analysis and Lab-on-Chip applications M.R.H. - Mechatronics based rehabilitation at home