1. Introduction
Spinal Cord Injury (SCI) is one of the most important traumas in adulthood, leading to long-term and probably permanent disabilities in patients. This type of injury is seen at all ages and in both genders (White & Black, 2016;
Yousefifard, et al., 2016). However, there is no definite cure to resolve all the symptoms of this disease. Thus, several treatment strategies have been proposed in recent years. These strategies range from pharmacological to cellular and molecular therapies, having often moderate efficacies, and none can entirely resolve the symptoms of SCI (
Hosseini et al., 2014;
Hosseini, Yousefifard, Aziznejad, & Nasirinezhad, 2015;
Hosseini et al., 2016;
Mojaradet al., 2016;
Nasirinezhad, Hosseini et al., 2016; Arash
Sarveazad et al., 2016;
Yousefifard, Nasirinezhad et al., 2016;
Yousefifard et al., 2016). The cause of this failure in treatment can be attributed to the pathophysiology and factors associated with SCI, which decrease the efficacy of the treatments. These factors include decreased growth mediators (
Lu et al., 2012), poor ability of the nervous tissue to repair spontaneously (
Finnerup & Baastrup, 2012), myelin-associated outgrowth inhibitors (
Filbin, 2003;
Simonen et al., 2003), and inhibitory factors related to glial scars, such as the upregulation of Chondroitin Sulfate Proteoglycans (CSPGs) (
Silver & Miller, 2004;
Yuan & He, 2013). Therefore, if these inhibitory factors are eliminated, acceptable treatment for SCI may be achieved.
Research has demonstrated that among the mentioned factors, the formation of glial scars and chronic inflammation is probably the most important factor in reducing the efficacy of treatment (
Muramoto et al., 2013;
Yuan & He, 2013). Glial scar, the most important component of which is the CSPGs, leads to the activation of pathways that inhibit tissue repair in the central nervous system. These proteoglycans are extracellular matrix molecules whose expression begins one day after the injury at the lesion site and reaches its maximum level a week later (
Jones, Margolis, & Tuszynski, 2003). CSPGs stimulate cascading pathways leading to the activation of Glycogen Synthase Kinase-3β (GSK3β), which is a key factor in inhibiting the repair of the central nervous system tissues and axons (
Dill et al., 2008). In recent years, studies have shown that the digestion of CSPGs using the bacterial enzyme chondroitinase ABC (ChABC) can promote axonal growth and ultimately improve sensory-motor function following SCI (
Dyck et al., 2015;
Shinozaki et al., 2016); however, in some studies, ChABC has had a moderate effect or was ineffective in the recovery process following SCI (
Alluin et al., 2014;
Zhao et al., 2013;
Zhao & Fawcett, 2013).
Although several studies have been conducted in recent years to investigate the efficacy of ChABC to treat SCI, inconsistencies in these studies have been an obstacle to drawing a possible conclusion. One way to achieve an overall result is to perform a systematic review and meta-analysis; however, no meta-analyses have been performed yet. Therefore, the present systematic review and meta-analysis aims to conduct a comprehensive and complete search of electronic resources to investigate the role of administrating ChABC in improving the complications following SCI.
2. Materials and Methods
Study design
To achieve the purpose of the present study, the PICO framework was defined as follows: problem (P): animals (rats or mice) with traumatic SCI; intervention (I): intravenous or intracranial administration of ChABC; comparison (C): comparison with non-treated SCI group or vehicle-treated group; outcome (O): locomotion assessment of the animals using appropriate tests, including the Basso, Beattie, Bresnahan (BBB) test, the grid walking test, the pellets retrieved test, and the ladder walking test. BBB is the most common test to assess motor function which is performed by capturing animals’ free movement on a circular field (open field walking test) for 4 min on a film, and each animal is blindly scored by 2 trained observers watching the film. The scoring is based on a 21-point scoring scale, categorizing recovery patterns into early (0 to 7), intermediate (8 to 13), and late phases (14 to 21) of recovery. The mean score for each animal is considered its BBB score (
Basso et al.,1995). The grid walking test is another examination that is performed on a grid runway (27 cm×180 cm), with 50×50 mm holes, and after training, the average number of limb placement errors in every run is calculated for each animal (
Kunkel-Bagden et al., 1993). In the pellets retrieved test, the animals were trained to reach food pellets through a 1.5 cm slot in an acrylic box (15 cm×36 cm×30 cm), and the number of pellets successfully retrieved out of 20 offered pellets will be calculated as the success rate (
Montoya et al., 1991). In the ladder walking test, animals’ walk on a 120-cm-long horizontal ladder with unevenly spaced bars is captured, and each step of each forepaw is given a score according to a 0–6 scoring system (0=total miss, 1=deep slip, 2=slight slip, 3=replacement, 4=correction, 5=partial placement, and 6=correct placement). The average score of each step for 3 rounds is calculated as the final score (
Metz & Whishaw, 2009).
Selection criteria
Studies on rats and mice that assessed the role of ChABC in SCI were included. The exclusion criteria were as follows: combination therapy, follow-up of fewer than 4 weeks, lack of non-treated SCI group, lack of locomotion assessments, studies performed on non-rodent species, and review studies. Since locomotion recovery in animal models requires at least 4 weeks of follow-up, studies with a follow-up period of fewer than 4 weeks were excluded as well.
Search strategy
The search was conducted using keywords related to SCI and ChABC. MEDLINE, Embase, Scopus, and Web of Science electronic databases were searched until the end of 2019. The Embase database search query was as follows:
‘chondroitin abc lyase’/exp OR ‘chondroitin abc eliminase’:ab,ti OR ‘chondroitin abc endolyase’:ab,ti OR ‘chondroitin abc lyase’:ab,ti OR ‘chondroitin sulfate abc endolyase’:ab,ti OR ‘chondroitin sulphate abc endolyase’:ab,ti OR ‘chondroitinase abc’:ab,ti OR ‘chondroitinases and chondroitin lyases’:ab,ti OR ‘condoliase’:ab,ti OR ‘anti-CSPG’:ab,ti OR ‘CSPGs’:ab,ti OR ‘Chondroitin sulphate proteoglycans’:ab,ti OR ‘chondroitinase’:ab,ti OR ‘Chondroitin Sulfate ABC Endolyas’:ab,ti
‘spinal cord injury’/exp OR ‘spinal cord contusion’/exp OR ‘spinal cord hemisection’/exp OR ‘spinal cord transection’/exp OR ‘cervical spine injury’/exp OR ‘Spinal compression’:ab,ti OR ‘spinal cord trauma’:ab,ti OR ‘trauma, spinal cord’:ab,ti OR ‘injured spinal cord’:ab,ti OR ‘spinal cord injured’:ab,ti OR ‘spinal cord injuries’:ab,ti OR ‘nerve transection’ #1 AND #2
To find additional articles, a manual search was done from the list of relevant articles and related journals. In addition, grey literature was explored by adopting 3 search strategies, namely ProQuest’s dissertation section, contacting the authors of related articles to obtain unpublished or pre-printed data, and using Google and Google Scholar search engines.
Data extraction
The articles obtained from the systematic and manual search in the present study were integrated using EndNote software (v. X7, Thomson Reuters, 2014) and duplicate articles were removed. Two independent reviewers studied the titles and abstracts of the initial screening articles. Afterward, the full texts of the potentially related articles were assessed. Disagreements were resolved using a discussion with a third researcher.
The extracted data included the first author’s name, year of publication, animal species, gender, age/weight of the animal, number of samples examined, SCI induction model, the severity of the injury, the time interval between SCI and ChABC prescription, ChABC treatment protocol, the duration of follow-up, and animal’s locomotion status on the last day of the follow-up. As in some cases, there was an article comparing several treatment protocols of ChABC, the data in these articles were recorded as separate experiments and entered into the analysis. Also, most animal studies present their findings in the form of diagrams. To overcome this limitation, the method of extracting data from charts was performed using Sistrom and Mergo with the help of the Plot Digitizer software (
Sistrom & Mergo, 2000).
Risk of bias assessment
The quality of the included studies was investigated using the proposed guidelines of Hassannejad et al. (
Hassannejad et al., 2016). Disagreements were resolved through discussion with a third researcher.
Statistical analysis
All statistical analyses were performed in the STATA 14.0 statistical program. To evaluate the efficacy of ChABC, the mean locomotion score of animals was compared between ChABC-treated groups and non-treated animals. The findings were pooled together and a Standardized Mean Difference (SMD) with a 95% Confidence Interval (CI) was reported. The heterogeneity between the studies was investigated using the I2 index, and since an obvious heterogeneity between the studies was observed, we used the random effect model. The Egger test and Funnel Plot were used to evaluate publication bias (
Egger, Smith et al., 1997).
3. Results
Study characteristics
The search resulted in 1,096 non-duplicate articles. After studying the titles and abstracts of these articles, 136 articles were regarded as potentially eligible to enter this review, and finally, 34 articles were included (
Bai et al., 2010;
Bradbury et al., 2002;
Caggiano et al., 2005;
Cheng et al., 2015;
Führmann et al., 2018;
García-Alías et al., 2009;
García-Alías et al., 2008;
García-Alías et al., 2011;
Grosso et al., 2014;
Huang et al., 2006;
Ishikawa et al., 2015;
Janzadeh et al., 2017;
Karimi-Abdolrezaee et al., 2010;
Kim et al., 2006;
Lee et al., 2012;
Liu, et al .,2018;
Mountney et al., 2013;
Ni et al., 2015;
Novotna et al., 2018;
Raspa, Bolla et al., 2019;
Sarveazad et al., 2017;
Sarveazad et al., 2014;
Shinozaki et al., 2016;
Takeuchi et al., 2013;
Tom et al., 2009;
Wang et al., 2011a;
Wang et al., 2011b;
Xia et al., 2017;
Xia et al., 2015;
Xiong et al., 2016;
Yang et al., 2009;
Yoo et al., 2013;
Zhao et al., 2013) (
Figure 1).
These 34 studies contained 44 separate experiments evaluating several different protocols, including variations in the SCI severity, the prescription method, the prescription dose, and the interval time between SCI and ChABC administration. Three experiments were performed on mice and 41 experiments were performed on rats. In these studies, 272 animals were in the non-treated SCI group and 340 animals were in the ChABC-treated SCI group. Eleven studies performed cervical SCI, 31 studies thoracic SCI, and 2 studies thoracolumbar SCI. Ten experiments used the contusion injury model, and 10 experiments used the transaction model. Compression, crash, and hemisection models were adopted in 8 experiments. The severity of SCI was moderate in 20 studies and severe in 24 studies. ChABC was administrated immediately after SCI in 33 experiments (ranging between 0 and 42 days). A total of 17 experiments used a single dose of ChABC, while 27 experiments used multiple or continuous doses of ChABC (using subcutaneous pumps). In multi-dose protocols, the number of doses varied between 2 and 14. The place of administration was intrathecal in 25 experiments and intraspinal in 19. The total dose received ranged from 0.024 U to 560 U, indicating a range from very low doses to very high doses. A total of 28 experiments followed the observer blinding principle. Moreover, the follow-up duration ranged from 4 to 15 weeks (maximum frequency=42 weeks). The most common locomotion test was BBB (32 experiments).
Table 1 demonstrates the characteristics of the articles, separately.
Quality assessment and publication bias
Risk of bias in bladder expansion, attrition, blinding of the observer, regulation, and ethics, and description of statistical analysis were high risk in 45.45%, 56.81%, 36.36%, 9.09%, and 6.81% of the studies, respectively. The risk of bias in other items was low.
Figure 2 and
Table 2 show the findings of this section. In the present study, no publication bias was observed (P=0.427) (
Figure 2).
Meta-analysis
ChABC administration moderately improves locomotion recovery after SCI (SMD=0.90; 95% CI: 0.61 to 1.20; P <0.001) (
Figure 3).
The presence of heterogeneity between studies (I2=66%; P<0.001) led to performing subgroup analysis (
Table 3).
Subgroup analysis revealed that the animals’ species does not affect the efficacy of ChABC treatment (P=0.218); however, a small number of experiments were performed on the mice subgroup (3 experiments) compared to the rat subgroup, and therefore, the analysis may not identify the differences between the subgroups. On the other hand, the location of the SCI had similarly no effect on the efficacy of ChABC treatment (P=0.632). However, in this analysis, only two experiments were performed on the thoracolumbar region. Thus, differences between the cervical, thoracic, and thoracolumbar injuries may not have been identified properly. Similar findings were observed regarding the phase of treatment. Analyses of subgroups discrepancies did not show any statistical differences between treatment in immediate-acute (26 experiments), subacute (12 experiments), and chronic (6 experiments) phases post-injury (P=0.431). The small number of experiments in chronic subgroups has resulted in the findings being uncertain. In addition to the above results, the difference between the total administered dose of ChABC did not affect the efficacy of ChABC treatment (P=0.488). Again, the small number of moderate and high dose experiments cast doubt over the adequacy of this analysis.
Regarding other factors, an acceptable number of experiments were entered in each subgroup. Therefore, with an acceptable confidence, it can be concluded that differences in the SCI model (P=0.732), the severity of the injury (P=0.821), the number of administrations (P=0.092), the blinding status (P=0.294), the use of different locomotor score (P=0.567), and the follow up duration (P=0.750) have no effect on the efficacy of ChABC treatment.
4. Discussion
The findings of the present study showed that prescribing ChABC has a moderate effect on the improvement of locomotion after SCI in rats and mice. The subgroup analysis showed that the efficacy of ChABC treatment is not affected by the differences in the SCI induction model, the severity of the injury, the number of ChABC administration, the blinding status, the use of different locomotor scores, and the follow-up duration.
The most important mechanism involved in improving motor function by prescribing ChABC after SCI is related to the restoration of neuronal plasticity in the spinal cord. SCI leads to the formation of a glial scar that is rich in CSPGs. Increased CSPGs after the central nervous system damage causes functional impairment both by preventing axonal regeneration and by preventing synaptic plasticity. The ChABC enzyme digests CSPGs, which, in addition to the axonal regeneration, by inducing axonal germination, restores lost circuits, neuronal plasticity, and ultimately functional changes (
Hyatt et al., 2010;
Massey et al., 2006;
Vitellaro-Zuccarello et al., 1998). In 2011, via a systematic review, Kwon et el. demonstrated that ChABC promotes axonal regeneration in the spinal cord. Their results showed that the enzyme was less effective in cervical or thoracic injury models, but when used as adjuvant therapy in combination with cell therapy, its effects on improving motor functions were much greater (
Kwon et al., 2011).
In the present meta-analysis, only studies that performed a follow-up of animals for at least 4 weeks were included. The reason for this choice was because it takes at least 4 weeks of follow-up to evaluate the effectiveness of a treatment for SCI models in rodents. Perhaps this is because the follow-up duration did not affect the efficacy of ChABC in improving locomotion. In other words, 4 weeks of follow-up was enough to see the effects of ChABC.
Using the single dose or multi-dose protocol did not affect the efficacy of ChABC treatment. Considering the course of motor improvement in animals with SCI in studies that have examined the effects of ChABC treatment on motor performance in rodents (
Janzadeh et al., 2017;
Sarveazad et al., 2017;
Sarveazad et al., 2014), we observed that during the first week, without any intervention, the motor performance dramatically improves, and then, the speed of recovery decreases. As a result, it seems that the first week of SCI treatment in rodents is the most important period in terms of improving motor function and SCI management. The half-life of ChABC is 6 days (
Lee et al., 2010). Since the use of the single dose or the multi-dose protocol did not affect the efficacy of ChABC treatment in the present study, it seems that the first dose of ChABC is the most important. Considering the half-life of ChABC, it can be concluded that this treatment is most effective in locomotion recovery during the first week following SCI. In other words, based on the half-life of the enzyme, if no prescriptions take place after the first dose, there is still enough amount of ChABC that can play a role in improving motor functions. The total dose received in most cases in single or multi-dose was similar. The prescribed dose in 76.5% of studies in the single dose group and 66.7% of studies in the multi-dose group was less than 1.7 U. Hence, there is still a need for further research to use different doses to become certain about the aforementioned conclusion.
Our results showed that prescribing ChABC has a moderate effect on the improvement of locomotion after SCI in rats and mice. Therefore, the combined application of ChABC and other therapeutic approaches may increase its effectiveness. For example, some studies used combinational therapy of ChABC along with stem cells, lasers, and various scaffolds (
Novotna et al., 2020;
Jevans et al., 2021;
Raspa et al., 2021). These studies show that the effect of co-administration of ChABC with these therapies is more effective than single therapies. For example,
Jevans et al. showed that co-administration of ChABC and neural stem cells had a greater effect on motor recovery compared to ChABC and cell therapy alone. Janzadeh et al. have reported similar findings in the simultaneous application of laser irradiation and ChABC administration (
Janzadeh et al., 2020). Therefore, in future studies, more attention should be paid to the effects of combinational therapy on SCI.
As a result, it can be concluded that the addition of other therapies to the ChABC regimen may prove beneficial. For instance, studies point out that ChABC was administered along with stem cells, laser therapy, and different scaffolds. These studies demonstrate that the co-administration of ChABC with these treatments is more effective than single therapies. As an example, Jevans et al. showed that combination therapy of ChABC with neural stem cells has a greater effect on motor recovery following SCI than ChABC treatment alone (
Jevans et al., 2021). Janzadeh et al. concluded the above-mentioned result as well (
Janzadeh et al., 2020). Hence, future studies are suggested to contemplate the efficacy of combination therapies.
Another finding of the present study was that the efficacy of ChABC treatment in different severities of the injury is the same. The reason for this finding is that gliosis occurs in all severities of the lesion, and the administration of ChABC, via digesting the CSPGs, can play a role in the regeneration process. In addition, the severity of the damage in all models was in the moderate to severe range. The secondary mechanisms in both injury severities are almost identical, and this is another justification that the administration of ChABC is equally effective in both severities. Furthermore, the subgroup analysis on the effect of the phase of treatment, region of the injury, and the total administrated dose in ChABC efficacy were unreliable. The number of studies conducted on mice was small; therefore, reliable conclusions may not be supported desirably in this regard. In addition, the number of studies included in the efficacy of ChABC treatment in the chronic phase of SCI was low. Hence, it cannot be concluded whether ChABC administration in the chronic phase is different from its administration in immediate-acute and subacute phases.
Another limitation of the present study is the incomplete reporting bias in some studies. This is a common bias in animal studies and its assessment is difficult as there is no public registry for animal studies.
5. Conclusion
The findings of the present study showed that prescribing ChABC has a moderate effect on improving locomotion following SCI in mice and rats. The analyses showed that the efficacy of ChABC treatment is not affected by the differences in the SCI model, the severity of the injury, the number of administrations, the blinding status, the use of different locomotor scores, and the follow-up duration.
Ethical Considerations
Compliance with ethical guidelines
This study received ethical approval from the Ethics Committee of Tehran University of Medical Sciences (Code: 96-01-38-34312). The study complies with the Declaration of Helsinki.
Funding
All expenses, charges, and costs, including software and hardware requirements in this research were supported by Sina Trauma and Surgery Research Center, Tehran University of Medical Sciences (Grant No: 96-01-38-34312).
Authors' contributions
Study design: Mostafa Hosseini, Mahmoud Yousefifard, Arash Sarveazad, Kosar Mohamed Ali; Data collection: Mahmoud Yousefifard, Atousa Janzadeh, Mohammad Hossein Vazirizadeh-Mahabadi; Data analysis: Mostafa Hosseini and Mahmoud Yousefifard; Drafting: Mahmoud Yousefifard; Critical Revision: All authors.
Conflict of interest
All authors declared no conflict of interest.
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