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Stress loading device and system for constructing stress fracture animal model and method

An animal model and stress loading technology, which is applied in the fields of animal restraint equipment, medical science, veterinary equipment, etc., can solve the problems of anesthesia, cumbersome and time-consuming process, stress fracture disjoint, etc. control effect

Active Publication Date: 2016-06-08
FOURTH MILITARY MEDICAL UNIVERSITY
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

However, the tensile loading mode is difficult to simulate the occurrence and development of stress fractures under physiological conditions
In addition, all current stress fracture modeling methods require anesthesia of experimental animals, which is even more out of touch with the real occurrence of stress fractures
[0006] Clinical basic research requires easy-to-obtain and standardized animal models. However, the current foreign modeling methods are cumbersome and time-consuming due to the need for anesthesia. The domestic modeling methods all indirectly exert stress on the bones by stimulating animal muscle overload exercise. , since the starting point of stimulation is different each time, the quality of the model may be uneven, and the positive rate and standardization of the model cannot meet the requirements

Method used

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  • Stress loading device and system for constructing stress fracture animal model and method
  • Stress loading device and system for constructing stress fracture animal model and method
  • Stress loading device and system for constructing stress fracture animal model and method

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Experimental program
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Effect test

Embodiment 1

[0040] See figure 1 , The stress loading device structure for constructing a rat ulna stress fracture animal model disclosed in the present invention includes a tissue fixation unit for fixing the bones of experimental animals. A laser displacement sensor 1 is provided on one side of the tissue fixation unit, and the other side A stress sensor 4 is provided, the other end of the stress sensor 4 is provided with a linear actuator 5, the tissue fixation unit, the stress sensor 4 and the linear actuator 5 are coaxially arranged, and a linear guide 6 is also provided under the tissue fixation unit. Among them, the tissue fixation unit includes a fixed ulnar chuck 2 for fixing the elbow joint of an experimental animal, and a movable ulnar chuck 3 for fixing the wrist joint of an experimental animal, see image 3 .

[0041] When establishing an animal model of a rat ulnar stress fracture, the ulna is fixed in a tissue fixation unit, the ulnar fixed chuck 2 is used to clamp the elbow joi...

Embodiment 2

[0048] See figure 2 , The stress loading device structure for constructing a stress fracture animal model of the rat tibia disclosed in the present invention includes a tissue fixing unit for fixing the bones of experimental animals. A laser displacement sensor 1 is provided on one side of the tissue fixing unit, and the other side A stress sensor 4 is provided. The other end of the stress sensor 4 is provided with a linear actuator 5. The tissue fixation unit, the stress sensor 4 and the linear actuator 5 are coaxially arranged, and a linear guide 6 is also provided under the tissue fixation unit. Among them, the tissue fixation unit includes a tibial fixed chuck 7 for fixing the upper joint of the tibia of an experimental animal, and a tibial movable chuck 8 for fixing the ankle. One piece is provided above the tibial fixed chuck 7 and above the tibial movable chuck 8. To prevent the tibia from slipping off, the tibia fixed chuck 7 is above the tibia long compression tablet 9...

Embodiment 3

[0054] The stress loading device disclosed in the present invention is used to establish a rat ulnar stress fracture animal model. The specific example is as follows: 5-month-old 550g male SD rat was purchased from the Experimental Animal Center of the Fourth Military Medical University, and 3% pentobarbital was injected intraperitoneally Sodium (30mg / kg) anesthetize the rat, fix the right ulna between the fixed chuck and the movable chuck in the tissue fixation module. The stress loading adopts the periodic dynamic loading method. The basic loading waveform is ramp loading, including 1.5N preload, 0.8 second ramp up and 0.8 second ramp down, by controlling the loading rate to generate a 30N ramp peak load waveform, the waiting time between the two loading cycles is 0.1 seconds, a total of 5000 cycles of loading .

[0055] After the in-body loading experiment is completed, microCT scans are used to compare the microinjuries of the ulna at the experimental end and the control end,...

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Abstract

The invention discloses a stress loading device and system for constructing a stress fracture animal model and a method, and belongs to the technical field of animal experiment models. The device comprises a tissue fixing unit for fixing experimental animal skeletons, a laser displacement sensor is arranged at one side of the tissue fixing unit, and a stress sensor is arranged at the other side of the tissue fixing unit. A linear actuator is arranged at the other end of the stress sensor, and the tissue fixing unit, the stress sensor and the linear actuator are coaxially arranged. A linear guide rail is further arranged below the tissue fixing unit. The invention further discloses a controllable stress fracture animal model construction system based on the stress loading device. The system comprises the stress loading device, a real-time data collecting and processing module and a PC side LabVIEW control program. The device is precise and controllable in loading strength and time, and the success rate of establishment of the model can be effectively increased.

Description

Technical field [0001] The invention belongs to the technical field of animal experimental models, and specifically relates to a stress loading device, a loading system and a method for constructing a stress fracture animal model. Background technique [0002] Stress fracture (SF) is a kind of fatigue fracture that often occurs in normal bones. After the muscles are overused and fatigued, they cannot absorb the vibrations caused by repeated collisions in time, and the stress is transmitted to the bones, which can only be found under a microscope. Micro damage. If this kind of micro-injury accumulates and exceeds the body's ability to repair itself, stress fractures will occur. Stress fractures are common in military training and training of athletes and dancers. It is not only the focus and difficulty of military medicine research, but also one of the key research topics of sports medicine. [0003] In 1855, Breihaupt officially published an article about stress fractures in the ...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): A61D1/00A61D3/00
CPCA61D1/00A61D3/00A61D2003/006
Inventor 景达罗二平张旭慧申广浩杨永清谢康宁刘娟康飞
Owner FOURTH MILITARY MEDICAL UNIVERSITY
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