One commonly used rat fracture model for bone and mineral research
is a closed mid-shaft femur fracture as described by Bonnarens in
1984. Initially, this model was believed to create very reproducible
fractures. However, there have been frequent reports of comminution
and varying rates of complication. Given the importance of precise
anticipation of those characteristics in laboratory research, we
aimed to precisely estimate the rate of comminution, its importance and
its effect on the amount of soft callus created. Furthermore, we
aimed to precisely report the rate of complications such as death
and infection. We tested a rat model of femoral fracture on 84 rats based on
Bonnarens’ original description. We used a proximal approach with
trochanterotomy to insert the pin, a drop tower to create the fracture
and a high-resolution fluoroscopic imager to detect the comminution.
We weighed the soft callus on day seven and compared the soft callus
parameters with the comminution status.Objectives
Methods
Background: Bacterial translocation is defined as a phenomenon in which live bacteria cross the intestinal barrier and spread the other systemic organs after various type of traumatic insults such as hemorrhagic shock, burn, malnutrition and abdominal trauma. It has also been shown that multiple fractures of long bones associated with head injury promote bacterial translocation. Aim: To determine whether early internal fixation of long bone fractures helps to prevent bacterial translocation. Materials and methods: Thirty-seven male Sprague-Dawley rats were divided into three groups. 1) anesthesia only (control group, n=12); 2) anesthesia + tibia fracture + femur fracture + moderate head trauma (trauma group, n=14), and 3) anesthesia + fixation of both tibia and femur fractures + moderate head trauma (fixation group, n=11). Head injury was created by using Marmarou’s impaction-acceleration model and fractures were created by using a
