Background
Spinal cord injury (SCI) often leads to paralysis and high morbidity. After SCI, a series of pathophysiological responses lead to progressive spinal cord tissue degeneration and necrosis, likely due to microcirculation disorders and neuron biochemical imbalance involving prostaglandins, calcium, neurotransmitters, and free radicals, considered one of the most important factors causing spinal cord tissue necrosis and degeneration [
1]. Neuronal cell membrane structures are rich in lipids, and research has found that lipid oxidation caused by free radicals has important implications on SCI outcome [
1,
2]. While some studies into SCI treatment have found that hyperbaric oxygen (HBO) can reduce the generation of oxygen free radicals in the body, thus reducing the oxygen free radicals caused lipid oxidation and accelerating SCI repair, other studies found opposite results [
3‐
5]. Therefore, HBO effect on nerve injury is yet to be elucidated.
This study investigates the HBO treatment of SCI in an experimental rat SCI model and examines HBO effect on the recovery of neuromotor functions. Serum malondialdehyde (MDA) and superoxide dismutase (SOD) levels were also measured. MDA is a lipid oxidation product generated through lipid peroxidation. The spinal cord neurons contain membrane structures rich in lipid, the oxidation of which during SCI further exacerbates neuronal damage. SOD is an enzyme that participates in superoxide radical scavenges that maintains the cellular oxidative and anti-oxidative balance, thus helping to eliminate the free radical damage to the cells and maintain normal cell functions. Therefore, the SOD and MDA levels in the body are a reflection of the extent of lipid peroxidation in injured cells [
2]. The joint determination of SOD activity and MDA content may indirectly reflect the extent of the free radical damage of the neuronal cells caused by SCI. Our hypothesis is that HBO treatment reduces lipid oxidation induced by SCI, thus accelerating recovery of neuromotor functions after SCI.
Methods
Experimental animals
The Ethics Committee of the Second Affiliated Hospital of Soochow University approved the protocol of the present study. A total of 45 healthy Sprague-Dawley female rats of clean-grade (15 rats in each group), 3 to 4 months old and weighing 215 to 300 g, were provided by the Experimental Animal Center of Suzhou University. During the experiments, the animals were treated in compliance with the “Guiding Opinions on the Ethical Treatments of Laboratory Animals” published by the Ministry of Science and Technology in 2006. All rats were randomly divided into three groups. Sham-SCI group was surgically exposed, but not subjected to the SCI procedure. SCI-control group was administered SCI and treated with regular air. SCI-HBO group was administered SCI and HBO treatment.
Experimental spinal cord injury model
In SCI-control group and SCI-HBO group, rats were administered SCI using the modified Allen weight-drop method [
6]. Briefly, rats were injected intraperitoneally with 3.6% chloral hydrate (1 ml / 100 g) under general anesthesia, and the spinal cord T11–12 plane area (about 4 mm × 8 mm) were exposed. A 2.5 mm diameter metal cylinder, weighing 10 g, was dropped from a height of 6.5 cm in a vertical plastic tube, directly onto the exposed spinal cord, resulting in acute moderate SCI with an injury force of 6.5 g*cm.
Neuromotor function assessment
The neuromotor functions of all the rats were examined by two technicians not involved in this study, using the Basso, Beattie, and Bresnahan (BBB) locomotor rating scale and the inclined plane assessment, at baseline, 1 h, 2, 5, 10 and 20 days after SCI [
7,
8]. For the inclined plane assessment, the inclination angle of the board is freely adjustable. The maximum inclination angle of the board on which the rat can stay for 5 s without falling off was recorded. The BBB rating scale has a range from zero to 21 points, judged by parameters such as coordination of limb movement, paw placement and tail balance. No visible movement of the hind legs is scored as 0 points. For the maximum 21 points, the rat has to walk continuously on the paws, with a cocked tail, good fore and hind limb motor coordination and truck stability. The toes have to grip the surface while moving forward and the paws maintain coordination with the body movement.
Hyperbaric oxygen (HBO) treatment
In the SCI-HBO group, HBO treatment began at two hours after SCI. A single-person medical hyperbaric oxygen chamber (Ningbo hyperbaric oxygen corporation, China) was prepared with flush of pure oxygen for ten minutes. The rats in the SCI-HBO group was put into the HBO chamber and exposed to 80% oxygen at 0.3 MPa (3ATA) for 60 min, followed by depress urization for 30 min. The HBO therapy was carried out once a day, for five days. The rats of SCI-control group treated with regular air.
Superoxide dismutase (SOD) and malondialdehyde (MDA) assay and spinal cord pathology
Tail blood (1.5 ml) was taken at baseline, two and five days after SCI, from which SOD activities and MDA levels were measured using the xanthine oxidase method and the thiobarbituric acid method (Nanjing Jiancheng Bioengineering Institute, China), respectively. At 20 days after SCI, the rats were sacrificed and the SCI pathology was examined with HE staining. Proteins were prepared from spinal cord tissue obtained from the lesion epicenter (2.5 mm cephalad and caudally).
Statistical analysis
All data are presented as mean ± standard deviation (SD). Statistical analyses were performed with the Prism software package (GraphPad v5, San Diego, CA, USA). Data were analyzed using two-way repeated measures ANOVA with bonferroni post-hoc testing, and then the Newman-Keuls test for multiple comparisons. A P-value less than 0.05 were accepted as statistically significant.
Discussion
According to our clinical experience, acute SCI patients usually need at least 7 days for HBO treatment. For rats recover more quickly than men, the time should be shortened. Furthermore, HBO application of 5 days is similar to the clinical therapy. This is why we chose this therapy time window in our study.
In our study, SCI female rats in the HBO treatment group had significantly improved neuromotor function than the control non-HBO treated SCI rats at 5, 10 and 20 days after injury, judged by both higher BBB scores and larger inclination angles in the inclined plane assessment. Serum SOD activities were significantly higher and MDA levels were significantly lower in the SCI rats of the HBO group than those in the control group, at both 2 and 5 days post-SCI, suggesting an increase in SOD activities and reduced lipid peroxidation caused by oxygen free radicals. This was consistent with the accelerated recovery of neuromotor function in SCI rats with HBO treatment. Our results showed that there was a significant difference between the SCI-control and sham-SCI in baseline SOD serum levels indicating that this is likely to be a false positive result. The probable reason of this false result is the limited sample size. Although SOD levels of the SCI-control was higher than the sham-SCI and SCI was able to reduce serum SOD as previous studies, these results were in line with the effect of SCI on SOD.
Our previous study has demonstrated that cystic degeneration could be achieved by treatment of SCI [
7]. And in this study, cystic degeneration was also observed from our results in the HBO treatment group. This histopathology changing indicated the curative effect of HBO.
MDA which is one of the most important products of membrane lipid peroxidation, exacerbates the damage of membrane. Therefore, it is necessary to study the mechanism of lipid peroxidation and the mechanism of lipid peroxidation. MDA plays an important role in mitochondrial respiratory chain complexes. The MDA content is a commonly used indicator in the study of plant senescence physiology and resistance physiology. SOD is a naturally occurring superoxide radical scavenger in the body, which can convert harmful superoxide radicals into hydrogen peroxide, and then protect the neuron cells. The combined determination of SOD activity and MDA can indirectly reflect the lipid peroxidation in vivo and the extent of the damage of the cells [
2].
Many mechanisms may participate in the accelerated restoration of neuromotor function by HBO treatment of SCI rats: (1) increased supply of oxygen to mitigate hypoxia and edema in the damaged tissue; (2) inhibition of neuronal apoptosis through regulation of apoptosis-related genes, thus promoting recovery of the reversible neurological injury [
9‐
14]; (3) increased expression of the hypoxia inducible factor to enhance hypoxia resistance [
15]; (4) reversal of the ischemia-induced decline in the expression of neurotrophic factors, thus reducing the formation of scar tissue to promote recovery of neurological function [
16]; (5) improvement of general antioxidant capacity of the body [
4,
17]. Our study shows that in SCI rats with improved neuromotor function through HBO therapy, serum SOD activities increased and MDA levels decreased, indicating that the inhibition of oxygen free radicals may be one of the mechanisms by which HBO treatment improved neuromotor function in SCI rats. After SCI, large amounts of oxygen free radicals are generated and released in the spinal cord tissue, due to ischemia, anoxia, and neuron mitochondrial redox transport chain uncoupling [
2]. The unstable unpaired electrons contained in the oxygen free radicals can attack the polyunsaturated fatty acids in the membrane structures of spinal cord neuronal cells, leading to lipid peroxidation, and cell and tissue damage [
1]. The neuronal membrane structures in the spinal cord are rich in lipids, and the oxidation of which generates aldehydes, ketones, hydroxyls, carbonyls, hydrogen peroxide and new oxygen free radicals, further exacerbating cell damage [
2,
18].
The effect of HBO treatment of acute SCI in clinical settings is controversial [
3‐
5]. Our previous studies have shown that HBO treatment clinically accelerates the functional recovery in rats with SCI [
19]. Acute SCI rats often have direct damage and even discontinuity of the spinal cord. The compression of spinal cord tissue by the fracture fragments results in local ischemia and local inflammatory response which led further spinal cord nerve tissue necrosis and apoptosis. So the most important clinical treatment of acute SCI is to repair the continuity of spinal cord, to relieve the compression of the local spinal cord tissue, and to further reduce the local and systemic inflammatory response. HBO therapy therefore is often not the immediate choice in acute SCI treatment. Nevertheless the neuronal tissue regeneration in SCI rats that require surgery remains a difficult task, due to the severe neuronal tissue damage; HBO therapy provides a better tissue environment for the repair and regeneration of injured spinal cord tissues, thus becoming part of a comprehensive effective treatment of SCI.
There are several weaknesses in our study. The modified Allen weight-drop method to inflict experimental SCI may cause only spinal shock or spinal cord concussion in some study rats, resulting in incomplete SCI. Secondly, the measurement of SOD and MDA were done at only Days 2 and 5 after SCI, compared to the neuromotor function assessment at up of Days 10 and 20 post-SCI. The lack of SOD and MDA measurements at later days of SCI makes it difficult to conclude that recovery of oxygen free radical homeostasis precedes the neuromotor function recovery after the HBO treatment. The role of HBO treatment in the relationship between oxygen free radicals and acute SCI needs further study.