Neuroprotective effects of alpha-lipoic acid on radiation-induced brainstem injury in rats
Elham Motallebzadeh1, Fatemeh Aghighi2, Zarichehr Vakili3, Sayyed Alireza Talaei2, Mehran Mohseni4
1 Physiology Research Center, Institute for Basic Sciences, Kashan University of Medical Sciences; Anatomical Sciences Research Center, Institute for Basic Sciences, Kashan University of Medical Sciences, Kashan, I.R. Iran
2 Physiology Research Center, Institute for Basic Sciences, Kashan University of Medical Sciences, Kashan, I.R. Iran
3 Department of Pathology, School of Medicine, Kashan University of Medical Sciences, Kashan, I.R. Iran
4 Anatomical Sciences Research Center, Institute for Basic Sciences, Kashan University of Medical Sciences; Department of Medical Physics and Radiology, Faculty of Paramedical Sciences, Kashan University of Medical Sciences, Kashan, I.R. Iran
Correspondence Address:
Mehran Mohseni
Anatomical Sciences Research Center, Institute for Basic Sciences, Kashan University of Medical Sciences; Department of Medical Physics and Radiology, Faculty of Paramedical Sciences, Kashan University of Medical Sciences, Kashan Tel: +98-9128957743, Fax: +98-3155540021
I.R. Iran
Source of Support: None, Conflict of Interest: None
CheckDOI: 10.4103/1735-5362.367798
Background and purpose: Alpha-lipoic acid (ALA) is an antioxidant with radioprotective properties. We designed the current work to assess the neuroprotective function of ALA in the presence of oxidative stress induced by radiation in the brainstem of rats.
Experimental approach: Whole-brain radiations (X-rays) was given at a single dose of 25 Gy with or without pretreatment with ALA (200 mg/kg BW). Eighty rats were categorized into four groups: vehicle control (VC), ALA, radiation-only (RAD), and radiation + ALA (RAL). The rats were given ALA intraperitoneally 1 h before radiation and killed following 6 h, thereafter superoxide dismutase (SOD), catalase (CAT), malondialdehyde (MDA), and total antioxidant capacity (TAC) in the brainstem were measured. Furthermore, a pathological examination was carried out after 24 h, 72 h, and five days to determine tissue damage.
Findings/Results: The findings indicated that MDA levels in the brainstem were 46.29 ± 1.64 μM in the RAD group and decreased in the VC group (31.66 ± 1.72 μM). ALA pretreatment reduced MDA levels while simultaneously increasing SOD and CAT activity and TAC levels (60.26 ± 5.47 U/mL, 71.73 ± 2.88 U/mL, and 227.31 ± 9.40 mol/L, respectively). The greatest pathological changes in the rat’s brainstems were seen in RAD animals compared to the VC group after 24 h, 72 h, and 5 days. As a result, karyorrhexis, pyknosis, vacuolization, and Rosenthal fibers vanished in the RAL group in three periods.
Conclusion and implications: ALA exhibited substantial neuroprotectivity following radiation-induced brainstem damage.
Keywords: Alpha-lipoic acid; Brainstem; Histopathology; Ionizing radiation; Oxidative stress.
While radiotherapy is an efficient treatment for brain tumors, it can damage adjacent normal tissue [1],[2],[3]. Ionizing radiation is widely recognized for inducing oxidative stress in target tissues, mostly by producing reactive oxygen species (ROS) [4],[5]. Various macromolecules, including malondialdehyde (MDA), are made as a final product of lipid peroxidation induced by ROS [6],[7].
Aerobic cells can strengthen their defense system against ROS flow by engaging in antioxidant activities that include both enzymatic and nonenzymatic mechanisms [8]. Amongst antioxidant enzymes, superoxide dismutase (SOD) catalyzes O2 reduction to H2O2, which is then degraded by catalase (CAT) to H2O and O2 [9]. Furthermore, prior research has shown that inflammation, vascular damage, the modified permeability of the cell membrane, and increased collagen synthesis are all important discoveries of brain tissue pathophysiology after radiation exposure [10].
Interestingly, the brainstem, located in the bottom region of the brain, is involved in essential processes such as conscious control, breathing, sleep, blood pressure, and pulse rate [11]. Furthermore, the brainstem is likely connected to an increment of nausea and vomiting toxicities since the postrema inside the brainstem is recognized as the vomiting-triggering area [12].
Because free radicals largely cause radiation-induced cellular damage, compounds having direct free radical scavenging abilities are particularly intriguing as radioprotectors [13],[14]. The development of innovative and efficient agents to prevent radiation damage utilizing nontoxic radio-protectors is of great interest in the defense in therapy [15],[16],[17].
Alpha-lipoic acid (ALA) is an endogenously generated coenzyme that is necessary for the processes of α-ketoacid dehydrogenases. Its antioxidant effects have lately been studied [18]. ALA and dihydrolipoic acid, the reduced form of ALA, both quench a variety of oxygen-free radical species available in the lipid and aqueous phases, chelates transition metals, and protect membrane lipids from peroxidation and protein degradation [19]. Several studies have demonstrated that ALA is a strong antioxidant with a radioprotective impact on lung damage. Moreover, it has reduced the infiltration of many inflammatory cells, fibrosis, edema, vascular and alveolar injuries [20]. Furthermore, ALA maintains the antioxidant state and functional structure of the cerebellum in the entire-body X-irradiated mice [21]. The purpose of this study was to study the impact of ALA on oxidative stress induced by X-rays, antioxidant state, and pathological alterations in the brainstem of rats.
Materials and methodsResearch units
Adult male Wistar rats, weighing 180-200 g, were purchased from Kashan University of Medical Sciences' animal house, Iran. The animals were kept in standard plexiglass cages (25 (w) × 45 (L) × 20 (h) cm) with four rats per cage under the standard conditions (12/12-h light/dark, 22-24 °C, and humidity of 50-55%) throughout the investigations. All rats were fed with the standard diet food (Pars Daam Animal Food Co., Iran) and watered with no limitations. All animal studies were conducted according to the ethical considerations and alternatives of The Ethical Committee, Deputy of Research and Technology, Kashan University of Medical Sciences. (Ethic No. IR.KAUMS.MEDNT.REC.1400.029).
Study design and radiation
As per the methodology of the study, 80 rats were categorized into four groups (n = 20) utilizing a randomized block design, which included vehicle control (VC), ALA, radiation only (RAD), and radiation + ALA (RAL). The rats were moved to a facility close to the Siemens Primus linear accelerator an hour prior to the tests began (Siemens AG, Erlangen, Germany) [22]. ALA (gifted by Raha Pharmaceutical Co., Isfahan, Iran) was given intraperitoneally to the ALA and RAL groups. ALA was solubilized (40 mg/mL) in 20% ethanol before dilution with distilled water. Every rat was given a 200 mg/kg solution of ALA [18] and the VC rats were treated with 20% ethanol [20],[23].
The animals were anesthetized intraperitoneally an hour following the treatment by administering 60 mg/kg ketamine and 20 mg/kg xylazine (Alfasan, The Netherlands) in the prone position. The RAD and RAL rats were subsequently subjected to radiation (whole-brain) at a single dose of 25 Gy [24] with a dosage rate of 200 cGy/min in a field area of 840 cm2 at a source surface distance of 100 cm [24],[25],[26]. The VC group received false radiation.
Preparation of tissue sample
Six hours following the rats were irradiated; they were anesthetized using intraperitoneal administrations of 20 mg/kg xylazine and 60 mg/kg ketamine [24],[27]. The rats’ brainstem tissues were extracted (n = 5 for biochemical tests in each group). The remaining rats were killed after the anesthesia process for pathological examinations at 24 h, 72 h, and five days following radiation.
Biochemical analyses
Measurement of MDA
According to the producer's instructions, the enzyme-linked immunosorbent assay (ELISA) technique was carried out to evaluate the amount of MDA activity (Zell Bio, Germany).
Measurement of antioxidant markers
According to the producer's protocol, the ELISA technique was utilized to measure the amount of CAT, SOD, and total antioxidant capacity (TAC) activity (Zell Bio, Germany).
Histopathological study
The samples underwent 48 h of fixation process using 10% neutral buffered formalin and then a dehydration procedure utilizing a serial dilution (70, 90, and 100%) of graded ethanol. Following that, the specimens were embedded in paraffin wax. Then, slices were serially cut at a thickness of 5 µm, stained with hematoxylin and eosin (H&E), and examined under a light microscope [28].
Statistical analysis
The data were reported as mean ± SD. The normality of the data was checked using the Shapiro-Wilk test, and then analyzed using one-way ANOVA followed by Tukey's posthoc test. P-values < 0.05 were considered significant.
ResultsThe effects of ALA on the biomarkers of oxidative stress
MDA concentrations in brainstem tissue homogenate were measured for six h following radiation. MDA levels in brainstem tissue were considerably greater in the RAD group (46.29 ± 1.64 μM) than in the VC group (31.66 ± 1.72 μM). MDA levels were considerably reduced (33.04 ± 1.16 μM) after pretreatment with 200 mg/kg ALA. Furthermore, there was no statistically meaningful difference in MDA levels between the ALA and VC groups [Figure 1].
Figure 1: The MDA levels (μM) in the brainstem tissues of rats in various research groups (n = 5 in each group). The data are provided as mean ± SD. ***P < 0.001 indicates significant differences compared to VC; and ###P < 0.001 versus RAD group. MDA, Malondialdehyde; VC, vehicle control; ALA, alpha-lipoic acid; RAD, radiation-only; RAL, radiation + ALA.The effects of ALA on the antioxidant biomarkers
[Figure 2] depicts the impacts of ALA on the activity of SOD and CAT in all examined groups. The antioxidants CAT and SOD activity were significantly reduced in the irradiated rats (RAD) compared with the VC group. [Figure 2] shows that CAT and SOD activity was substantially higher in the RAL group compared with the RAD group.
Figure 2: Enzyme activities of (A) CAT and (B) SOD in the brainstem tissues of rats in various study groups (n = 5 for each). Data are shown as mean ± SD. ***P < 0.001 indicates significant differences compared to VC; and ###P < 0.001 versus RAD group. CAT, Catalase; SOD, superoxide dismutase; VC, vehicle control; ALA, alpha-lipoic acid; RAD, radiation-only; RAL, radiation + ALA.The effects of ALA on the total antioxidant capacity
[Figure 3] indicates TAC activity in brainstem tissues was at lower levels in the RAD group (125.98 ± 7.27 mol/L) in comparison with the VC group (219.24 ± 10.36 mol/L). Furthermore, pretreatment with 200 mg/kg ALA substantially increased TAC activity in the rats’ brainstems (227.31 ± 9.40 mol/L). The level of TAC, however, did not change significantly between the VC and ALA groups (232.78 ± 7.02 mol/L).
Figure 3: TAC activity in the rats’ brainstems in various study groups (n = 5 for each). Data are shown as mean ± SD. ***P < 0.001 indicates significant differences compared to VC; and ###P < 0.001 versus RAD group. TCA, Total antioxidant capacity; VC, vehicle control; ALA, alpha-lipoic acid; RAD, radiation-only; RAL, radiation + ALA.The effects of ALA on the histopathology of the rats’ brainstem
[Figure 4] depicts an evaluation of H&E-stained slices from control rats that indicated no pathologic alterations (panel A). Polymorphic and pyramid cells were seen in the brainstem of control rats. Those that received ALA (panel B) had a normal histological pattern as well. Many degenerative abnormalities were detected in the RAD rats' brainstems. There was no sign of polymorphic cells. As a result, polymorphic cells might be more susceptible to radiation compared with pyramidal ones. Congestion and pyknosis were observed on photomicrographs of the brainstems of the irradiated rats (panel C). In addition, microglial nodules and Rosenthal fibers were seen 24 h following radiation (panels D and E). Karyorrhexis was observed 72 h following radiation (panel F). Furthermore, Rosenthal fibers and microglial nodules were seen in the brainstem. Following five days, the cell population in the tissue was reduced (panel G). Following five days, the next panels showed hyperemia and vacuolization (panels H and I). Inflammation, congestion, and pyknosis were diagnosed at the entire time points following radiation. Notable pathological alterations such as karyorrhexis, pyknosis, Rosenthal fibers, and vacuolization vanished in the RAL group after three-time points (panels J, K, and L).
[TAG:2]DISCUSSION
There exists a lot of interest in finding and producing non-toxic radioprotective chemicals. An effective radioprotector might be useful in therapeutic settings that employ ionizing radiation. The major findings of our study verified ALA's radioprotective properties in the brainstem of radiated (whole-brain) rats [29]. The findings of this study also showed that ALA effectively alleviates morphological degenerations induced by radiation and influences oxidative stress as well as antioxidant elements.
Numerous researches have been conducted to analyze the protective impact of ALA on normal tissue cells [19],[20],[21],[30]. Nonetheless, to our best knowledge, this in vivo study is the first try to explore the protecting properties of ALA toward the degenerative impacts of X-rays on the brainstems of rats. ALA is a powerful antioxidant that eliminates free radicals by recycling alpha-tocopherol and ascorbic acid [31]. Various investigations have indicated that ALA may have radioprotective properties in some murine organs, including the thyroid and intestine [32],[33]. Radiotherapy degenerates cells and tissues through DNA interaction or the production of harmful free radicals. Nevertheless, free radicals are responsible for above two-thirds of the degenerative properties [34]. MDA levels rise when ROS interacts with the unsaturated forms of membrane free-fatty acids, indicating lipid peroxidation activity. The anti-lipid peroxidation (radiation-induced) activity of ALA is owing to its free-radical scavenging abilities [35],[36],[37]. Our research results are in agreement with the findings in the brain tissues, shown by Manda et al. which demonstrated that the protective properties of ALA pretreatment regarding MDA content were greatest in the brain when compared to other tissues, including the testis, kidney, spleen, as well as the liver [19]. According to previous researches, ALA is extremely efficient in protecting against lipid peroxidation induced by stress [38],[39].
Moreover, the whole-brain X-raying of rats reduced CAT and SOD activity in brainstem tissues, most likely due to oxidative enzyme inactivation leading to increased ROS generation [2],[40]. Nevertheless, the ALA treatment of rats led to a rise in antioxidant enzyme activity and a reduction in lipid peroxidation [30]. Notably, Said et al. demonstrated ALA's antioxidant ability through restored levels of GSH and CAT activity, as well as preventing the lipid peroxidation process in radiation-exposed animals treated with ALA compared with those that were not received ALA [41]. As a result, the level of TAC in the rats’ brainstem tissues was substantially greater in the RAL group than in the RAD group. Accordingly, Manda et al. demonstrated that TAC plasma levels in ALA pretreatment groups were considerably greater than in their equivalent VC groups within cerebellum tissue [21].
Histopathological investigations revealed that the brainstems of the VC and ALA groups show a normal histological pattern, including polymorphic and pyramid cells, which is consistent with our biochemical test results. Alpha-lipoic acid can neutralize free radicals directly and has been shown to reduce radiation-induced oxidative stress [21]. Given that ionizing radiation induces oxidative stress via the generation of reactive oxygen species (ROS) and free radicals in irradiated tissue [23]. We expected that according to the results of previous studies on other organs [18], the treatment group alone did not have any pathological changes. According to our expectations, no harmful effect of ALA was seen in brainstem tissue either. Rosenthal fibers and microglial nodules were found in photomicrographs of the irradiated rats’ brainstems 24 and 72 h following radiation. However, karyorrhexis was only observed 72 h following radiation. The tissues showed reduced cell population, hyperemia, and vacuolization following five days. Furthermore, inflammation, congestion, and pyknosis were observed at all time periods. Previously, histopathological alterations in the brain of rats exposed to γ-radiation were studied, including pyknosis, vacuolization, as well as focal gliosis [42]. Also, pathological alterations, including microglial and inflammatory reactions, were found in the brain tissue of the rats following a dose of 20 Gy administered to the entire brain [43]. Our findings are aligned with the findings indicated by Manda et al. They found that ALA treatment decreases or eliminates a variety of pathological abnormalities in cerebellum-irradiated mice, including Purkinje cell migration, vacuolation, and necrosis [21],[44]. Polymorphic cells, contrary to pyramid cells, were not seen in the irradiated groups, possibly attributed to their susceptibility to radiation. At three time points, before radiation, ALA treatment eliminated part of the damage induced by radiation within the brainstem, such as karyorrhexis, pyknosis, vacuolization, and Rosenthal fibers.
ConclusionOverall, our data suggest that ALA may have a neuroprotective activity against oxidative stress induced by radiation and pathological modifications in the brainstems of rats. As a result, using this drug may allow patients to be exposed to greater radiation doses during radiotherapy, improving their life quality and therapeutic ratios. Nonetheless, additional clinical and experimental research is needed to reach a reliable conclusion in this respect.
Acknowledgments
This study was financially supported by the Deputy of Research and Technology, Kashan University of Medical Sciences, Kashan, Iran through Grant No. 99253.
Conflict of interest statement
The authors declared no conflict of interest in this study.
Authors’ contribution
S.A. Talaei, E. Motallebzadeh, and M. Mohseni designed the study. M. Mohseni, F. Aghighi, and Z. Vakili performed all the experiments and collected the data. S.A. Talaei, E. Motallebzadeh, and Z. Vakili analyzed and interpreted the data. E. Motallebzadeh and S.A. Talaei drafted the manuscript. All the authors read and approved the final version of the manuscript.
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