ABSTRACT
Objective:To explore the application effect of an intelligent teaching robot system of lifting manipulation in cervical spine manipulation teaching.Methods:60 doctors were randomly divided into an experimental group ( n = 30) and a control group ( n = 30). The control group was taught by a certified chief physician using a combination of "PowerPoint presentations, video demonstrations, and operation demonstrations" . Each part is 5 min. The experimental group was taught by the intelligent teaching robot system with a spinning technique. The teaching time is 15 min for both groups. At the end of the two teaching sessions, the two groups were trained five times under different BMIs and passed the system assessment. The qualified rates of pre-traction force, lifting and pulling force, maximum force, pre-traction time, lifting and pulling time, rotation amplitude, and pitch amplitude were compared between the two groups. Results:In normal, there was significant differences between the qualified rates of pre-traction force, lifting and pulling force, maximum force, pre-traction time, lifting and pulling time, rotation amplitude, and pitch amplitude in two groups (all P<0.05). For overweight people, there were significant differences in pre-traction force, pulling force, maximum force, and rotation amplitude (all P <0.05), while there were no significant differences in pre-traction time, pulling time, or pitching amplitude (all P >0.05). In obesity, there were significant differences in pre-traction force, lifting and pulling force, maximum force, and pitch amplitude (all P <0.05), but no significant differences in pre-traction time, lifting and pulling time, or rotation amplitude (all P >0.05). Conclusions:The proposed system can improve the pass rate of spinning manipulation, especially by effectively controlling the pre-traction force, pulling force, and maximum force.
ABSTRACT
Objective To investigate the feasibility of manual reduction with inverse shift for pronation-extorsion trimalleolar fracture by applying the finite element method combined with clinical experience. Methods Based on CT images and anatomical features of bone, ligaments and other tissues as well as material parameters, a normal ankle model with completed muscles and bones for a Chinese young male was established. According to the related characteristics of the pronation-extorsion trimalleolar fractures, fracture was simulated in the proper position to make osteotomy model. The finite element model of pronation-extorsion trimalleolar fractures was thus established and then applied with mechanical loading to simulate manual reduction with inverse shift. Results The established finite element model of pronation-extorsion trimalleolar fractures was effectively restored by the displacement loading. Conclusions The finite element analysis on pronation-extorsion trimalleolar fractures by inverse shift maneuver could further prove the feasibility, effectiveness and scientificity of manual reduction with inverse shift based on clinical experience.