INTRODUCTION: During the drilling of the bone, the temperature could increase above 47 degrees C and cause irreversible osteonecrosis. The spatial distribution of increase in bone temperature could only be presumed using several thermocouples around the drilling site. The aim of this study was to use infrared thermographic camera for determination of spatial distribution of increase in bone temperature during drilling. MATERIALS AND METHODS: One combination of drill parameters was used (drill diameter 4.5 mm; drill speed 1,820 rpm; feed-rate 84 mm/min; drill point angle 100 degrees) without external irrigation on room temperature of 26 degrees C. The increase in bone temperature during drilling was analyzed with infrared thermographic camera in two perpendicular planes. Thermographic pictures were taken before drilling, during drilling with measurement of maximal temperature values and after extraction of the drill from the bone. RESULTS: The thermographic picture shows that the increase in bone temperature has irregular shape with maximal increase along cortical bone, which is the most compact component of the bone. The width of this area with the temperature above critical level is three times broader than the width of cortical bone. From the front, the distribution of increase in bone temperature follows the form of the cortical bone (segment of a ring), which is the most compact part and causes the highest resistance to drilling and subsequent friction. CONCLUSIONS: Thermography showed that increase in bone temperature spreads through cortical bone, which is the most compact and dense part, and generates highest frictional heat during drilling. The medullar cavity, because of its gelatinous structure, contributes only to thermal dissipation.
INTRODUCTION: During the drilling of the bone, the temperature could increase above 47 degrees C and cause irreversible osteonecrosis. The spatial distribution of increase in bone temperature could only be presumed using several thermocouples around the drilling site. The aim of this study was to use infrared thermographic camera for determination of spatial distribution of increase in bone temperature during drilling. MATERIALS AND METHODS: One combination of drill parameters was used (drill diameter 4.5 mm; drill speed 1,820 rpm; feed-rate 84 mm/min; drill point angle 100 degrees) without external irrigation on room temperature of 26 degrees C. The increase in bone temperature during drilling was analyzed with infrared thermographic camera in two perpendicular planes. Thermographic pictures were taken before drilling, during drilling with measurement of maximal temperature values and after extraction of the drill from the bone. RESULTS: The thermographic picture shows that the increase in bone temperature has irregular shape with maximal increase along cortical bone, which is the most compact component of the bone. The width of this area with the temperature above critical level is three times broader than the width of cortical bone. From the front, the distribution of increase in bone temperature follows the form of the cortical bone (segment of a ring), which is the most compact part and causes the highest resistance to drilling and subsequent friction. CONCLUSIONS: Thermography showed that increase in bone temperature spreads through cortical bone, which is the most compact and dense part, and generates highest frictional heat during drilling. The medullar cavity, because of its gelatinous structure, contributes only to thermal dissipation.
Authors: Stephan Brand; Johannes Klotz; Maximilian Petri; Max Ettinger; Thomas Hassel; Christian Krettek; Thomas Goesling; Friedrich-Wilhelm Bach Journal: Int Orthop Date: 2013-03-20 Impact factor: 3.075
Authors: Carlo Fornaini; Elisabetta Merigo; Paolo Vescovi; Mauro Bonanini; Walter Antonietti; Luca Leoci; Giuseppe Lagori; Marco Meleti Journal: Lasers Med Sci Date: 2014-07-03 Impact factor: 3.161
Authors: Stephan Brand; Johannes Klotz; Thomas Hassel; Maximilian Petri; Max Ettinger; Christian Krettek; Thomas Goesling; Friedrich-Wilhelm Bach Journal: Int Orthop Date: 2013-06-18 Impact factor: 3.075
Authors: Carlo Fornaini; Marco Meleti; Mauro Bonanini; Giuseppe Lagori; Paolo Vescovi; Elisabetta Merigo; Samir Nammour Journal: ScientificWorldJournal Date: 2014-07-03
Authors: Luca Lamazza; Girolamo Garreffa; Domenica Laurito; Marco Lollobrigida; Luigi Palmieri; Alberto De Biase Journal: Biomed Res Int Date: 2016-03-24 Impact factor: 3.411