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Related Concept Videos

Assessing Body Temperature - Temporal Artery01:19

Assessing Body Temperature - Temporal Artery

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Here is a stepwise guide to assessing the body temperature at the temporal artery using a temporal artery thermometer
Step 1: Perform hand hygiene and don a fresh pair of gloves to prevent cross-infection and ensure patient safety.
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Assessment of Thermal Damage from Robot-Drilled Craniotomy for Cranial Window Surgery in Mice
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Experimental study of temperature rise during bone drilling process.

Jianbo Sui1, Chengyong Wang1, Naohiko Sugita2

  • 1Department of Manufacturing Engineering, Guangdong University of Technology, 100 Outer Ring West Road, Panyu District, Guangzhou 510006, China.

Medical Engineering & Physics
|February 12, 2020
PubMed
Summary

Excessive heat during bone drilling damages bone tissue. This study found drill bit geometry, drilling parameters, and bone type significantly impact temperature rise, offering insights for safer surgical procedures.

Keywords:
BoneDrillingResponse surface methodologyTaguchi methodTemperature rise

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Area of Science:

  • Biomedical Engineering
  • Orthopedic Surgery
  • Materials Science

Background:

  • Elevated temperatures during bone drilling can lead to osteonecrosis and impaired osteogenic potential.
  • A comprehensive understanding of factors influencing bone drilling temperature rise is lacking.
  • Investigating drill geometry, process parameters, and bone type is crucial for minimizing thermal damage.

Purpose of the Study:

  • To investigate the influence of surgical drill bit geometry, drilling process parameters, and bone type on temperature rise during bone drilling.
  • To identify significant drill geometric parameters and their interactions affecting temperature rise.
  • To develop a predictive model for temperature rise using response surface methodology.

Main Methods:

  • Utilized thermocouples for precise temperature measurement during bone drilling.
  • Employed three separate experimental designs to isolate the effects of geometric parameters, process parameters, and bone type.
  • Applied response surface methodology to develop a quadratic model for temperature prediction.

Main Results:

  • Temperature rise is significantly influenced by surgical drill bit geometry, drilling process parameters, and bone type.
  • Drill point angle and the interaction between web thickness and helix angle showed a highly significant effect on temperature rise.
  • The developed quadratic regression model accurately predicts temperature rise across various drilling conditions.

Conclusions:

  • Drill bit design, drilling parameters, and bone characteristics are critical determinants of thermal effects in bone surgery.
  • Optimized drilling parameters derived from the predictive model align well with experimental findings.
  • This research provides a foundation for developing strategies to mitigate thermal damage during orthopedic drilling procedures.