Adult ; Case-Control Studies ; Female ; Humans ; Male ; Middle Aged ; Orthopedic Procedures ; Popliteal Cyst ; surgery ; Suture Techniques

OBJECTIVETo establish an animal model of tractive spinal cord injury in rats in order to investigate its pathophysiological changes and clinical significance.

METHODST(12)-L(3) spines were tracted longitudinally with a special spinal retractor that was put on the proccessus transverses of T(12)-L(3) vertebrae of the rat after exposing T(13)-L(2) spinal cord via dual laminectomy. At the same tine, the spinal cord function was monitored by cortical somatosensory evoked potential (CSEP). Rats were randomly divided into four groups according to the amplitude of CSEP P(1)-N(1) wave, the amount of the decreasing P(1)-N(1) wave was 30% (the 30% group), 50% (the 50% group) and 70% (the 70% group), respectively. After traction, the changes of the neural behavioral function in rats were observed and the morphological structure of the spinal cord was analyzed quantitatively with image analysis system of computer.

RESULTSWith traction of spine, compared with the control group, the 30% group had no marked difference in combined behavioral score (CBS), neuron count, section area of neuron and Nissl body density, but the 50% and 70% groups had marked difference (P<0.01). Light microscope showed that the neuron volume was slightly small and the Nissl body was reduced lightly in the 30% group; the neuron space was enlarged and the neuron was degenerative, reductive, and dissolved, and the spinal cord structure was destroyed in the 50% and 70% groups.

CONCLUSIONSThe animal model of tractive spinal cord injury in rats is a reproducible, graded and clinic mimic. The model in this article provides a valuable assistance in further understanding etiopathology and screening effective measures of therapy and prophylaxis of the injury.

Animals ; Female ; Male ; Models, Animal ; Rats ; Rats, Sprague-Dawley ; Spinal Cord Injuries ; physiopathology ; Traction

Objective:To observe the effect of Dredging Correcting Manipulation on cblC methylmalonic aciduria (MMA). Methods:From October, 2017 to October, 2018, 72 children with cblC MMA combined with growth retardation were divided into control group (n = 36) and experimental group (n = 36) according to the consent of their parents. The control group accepted routine medicine, and the experimental group received Dredging Correcting Manipulation in addition. The Griffiths Development Scale-Chinese version (GDS-C) was used to evaluate the two groups before and after treatment. At the same time, body length, body mass and head circumference were measured. Results:Six cases in the control group and five cases in the experimental group were dropped out. There was no significant difference in the development quotients of GDS-C in gross movement, personal and social, hearing and speech, hand-eye coordination, operation and total quotient between two groups before treatment (P > 0.05). After treatment, all the development quotients increased in both groups (t > 6.110, P < 0.001), and the development quotients of GDS-C in gross movement, personal and social, hand-eye coordination and total quotient were higher in the experimental group than in the control group (t > 2.154, P < 0.05), as well as the body length (t = 2.027, P < 0.05). Conclusion:Dredging Correcting Manipulation can promote the neuropsychological and physical development of children with cblC MMA combined with retardation.