Background
Environmental pollution is a global menace that negatively impacts the health of a myriad of individuals, resulting in the development of various disease conditions. Arsenic is an environmental pollutant and a carcinogen, that pollutes the environment naturally and by human activities [
1]. Arsenic poisoning could occur by the consumption of arsenic-contaminated food and drinking water [
1,
2]. High levels of arsenic in groundwater, has been detected in some countries like Nigeria [
3,
4]. It is on record that an estimated 200 million people Worldwide are susceptible to health impairment due to high levels of arsenic in drinking water [
5]. Arsenic has been reported to orchestrate hepatotoxicity via the induction of oxidative stress [
6]
. Furthermore, studies have shown that, liver function is compromised in different animal species by exposure to sodium arsenite [
7].
The use of plants as medicine has been embraced by most Locals for several reasons, mostly because of the very high cost of orthodox drugs, and the recent re-emergence and dependence on medicinal plants in the treatment of disease conditions. Different parts of
Irvingia gabonensis (edible bush mango) are utilized as medicines by Locals in combating various ailments [
8]. The leaves are used as anti-poisons [
9]. The Senegalese use the decoction of the stem bark in treating ailments such as gonorrhea, liver and gastrointestinal diseases and the root bark is used to treat wounds [
9]. The stem bark has also been documented to possess bactericidal and fungicidal properties as well as in the treatment of yellow fever, hernias, dysentery and to mitigate poisons [
10,
11]. In addition, the antitoxic effects of the leaves in Wistar rats have been documented by various researchers [
12‐
15]. However, there is paucity of information on the antioxidant and medicinal effects of ethanol leaf extract of
Irvingia gabonensis against arsenic-induced hepatic dysfunction.
Discussion
Reactive oxygen species (ROS) and reactive nitrogen species (RNS), when in excess, are generally known to orchestrate the induction of oxidative stress in vivo, which underlies the etiologies of various disease conditions [
24]. Bioactive agents, especially those of plant origin, that have the capacity to mitigate the noxious effects of ROS, are of promise in combating the plethora of diseases, linked to oxidative stress [
25]. Enzymes called nitric oxide synthases, are involved in the production of the free radical, nitric oxide (NO
.) in biological tissues [
26]. The enzymes catalyze the conversion of the amino acid, arginine to citrulline, while forming NO
. via a five-electron oxidative reaction [
27]. Some negative health conditions such as dizziness, blurred vision, unusual bleeding, confusion, headache, and rapid heart rate, have been linked to excessive production of NO
.. Hydrogen peroxide (H
2O
2) is a reactive oxygen species that is capable of decomposing rapidly into water and oxygen, which may ultimately lead to the generation of hydroxyl radical (OH
.) that could initiate lipid peroxidation and DNA damage. Exposure to H
2O
2 could be through eye/skin contact or by the inhalation of vapour or mist [
26]. In the present study, ELEIG scavenged NO
. and H
2O
2 in a concentration-dependent manner, comparable to ascorbic acid (standard). This implies the potent antioxidant property of the extract which may not be unconnected with its inherent phytochemicals that have been reported to possess high antioxidant properties [
28].
The liver is a rich source of the aminotransferases, AST and ALT [
29]. These enzymes are involved in transamination reactions [
30]. In hepatocellular damage (which could by exposure to toxic elements), the blood levels of these enzymes are elevated. Their blood levels directly reveal the extent of tissue damage [
31].
In this study, administration of sodium arsenite (SA) culminated in significant increases in serum levels of AST and ALT, relative to the normal control. This implies hepatocellular damage by SA, leading to the leakage of the enzymes into the blood stream [
32]. This is corroborated by findings from previous studies [
33,
34]. Treatment with ELEIG (concomitant and post-treatment), achieved significant decreases in AST levels at the highest dose of 400 mg/kgbw when compared group 2 (administered sodium arsenite only). In the same vein, treatment with ELEIG produced significant decreases in ALT levels in dose-dependent manner when administered after 2 weeks of SA intoxication (post-treatment) and in dose-independent manner when administered concomitantly, compared with group 2 (administered SA only). This connotes that the extract could be ameliorative or curative. Administration of graded doses of ELEIG alone produced non-significant differences in AST and ALT levels, but significant decreases at the highest dose of 400 mg/kgbw, when compared with the normal control. The observed positive effect of the ethanol leaf extract may not be unconnected to its constituent antioxidant phytochemicals [
28], since sodium arsenite / arsenic has been reported to elicit its negative health effects by induction of oxidative stress, among others [
6]
.
Alkaline phosphatases (ALPs), catalyze hydrolysis of organic phosphate in proteins, nucleotides and alkaloids at alkaline pH [
35]. They are found in several tissues but high concentrations occur in liver, bone and kidney tissues as well as placenta and intestinal wall [
36]. An increase in serum ALP activity connotes occurrence of liver and bone diseases [
37]. It is also indicative of obstruction of bile ducts [
36]. Xenobiotic-induced hepatotoxicity, may also increase serum ALP activity [
38]. The degradation of glutathione in mammalian cells is catalyzed by gamma-glutamyltransferase (GGT), a cell-surface protein found in several tissues [
39]. However, a higher percentage of serum GGT is derived from the liver [
40]. Diseases of the liver, biliary system and pancreas, are associated with increased serum GGT activity. High blood level of GGT is closely related to hepatic steatosis [
41].
In this study, oral exposure of the experimental rats to sodium arsenite caused significant increases in serum ALP and GGT activities, relative to the normal control. However, treatment with graded doses of ELEIG (concomitant and post-treatment), led to significant decreases in serum ALP levels in dose-dependent manner compared with group 2 (administered sodium arsenite only). In the same vein, concomitant and post-treatment with graded doses of ELEIG also led to significant decreases in serum GGT levels in dose-independent manner compared with group 2 (administered sodium arsenite only). Furthermore, administration of graded doses of ELEIG alone produced non-significant differences in GGT levels and significant increases in ALP levels compared with control. This is therefore suggestive of the hepatoprotective effect of ethanol leaf extract of
Irvingia gabonensis which may have been influenced by its inherent antioxidant phytochemicals [
28]. Previous studies had also reported the hepatoprotective effects of ethanol leaf extract of
Irvingia gabonensis under conditions of induced toxicity [13, 14].
Bilirubin, the end product of haemoglobin catabolism [
32], is a biomarker of hepatic and blood disorders. An increase in serum bilirubin level indicates the occurrence of liver disease. Increase in blood levels of conjugated (direct) bilirubin, occurs in diseases such as hepatocellular damage, toxic or ischemic liver injury and viral hepatitis [
32,
42]. In this study, oral exposure of the experimental animals to sodium arsenite caused non-significant increases in serum total bilirubin (TBIL) and direct bilirubin (DBIL) concentrations, relative to the control. This indicates the interference with the transport function of the liver by sodium arsenite [
32]. However, there were no significant differences in serum TBIL and DBIL concentrations on treatment with ELEIG. Administration of ELEIG alone also produced non-significant differences in serum TBIL and DBIL concentrations as compared with control.
Arsenic, a heavy metal, induces oxidative stress by generating free radicals / ROS [
43] that culminate in cellular damage via depletion of enzyme activities through lipid peroxidation and reaction with nuclear proteins and DNA [
44]. Inorganic arsenic compounds can also induce oxidative stress by inhibiting antioxidant enzymes via binding to their sulfhydryl (−SH) groups [
45].
In this study, administration of sodium arsenite alone produced significant decreases in hepatic SOD and GPx levels and significant increases in CAT and MDA levels when compared with the control group. Endogenous enzymes act as the first line of cellular defense against reactive oxygen species [
46]. Oxidative stress leads to a loss in the balance between ROS production and antioxidant defense systems due to the overwhelming power of prooxidants generated, which deregulates cellular functions that can lead to hepatic necrosis [
47]. The observed significant increase in hepatic CAT level in this study may be due to significant induction in catalase activity as an adaptive response for combating the induced oxidative stress. This is consistent with the findings of Gbadegesin et al. [
13]. Catalase is the antioxidant enzyme that degrades hydrogen peroxide (a reactive oxygen species) produced during metabolism. It catalyzes the removal of hydrogen peroxide formed in the reaction catalyzed by superoxide dismutase [
48]. Superoxide dismutase (SOD) enhances dismutation of superoxide radical to hydrogen peroxide that is then removed by catalase [
49]. It may therefore serve as a primary defense and mitigates further production of free radicals. Glutathione peroxidases (GPx) facilitate the reduction of hydrogen peroxide and lipid hydroperoxides (products of lipid peroxidation) to their corresponding alcohols [
50]. Malondialdehyde (MDA) is a product of lipid peroxidation whose concentration in increased in oxidative stress that can lead to the destabilization of membranes [
34]. The mechanism of sodium arsenite-induced toxicity in this study may therefore be by its inhibition of antioxidant defense systems via the generation of ROS, culminating in the destabilization of cell membranes by lipid peroxidation. Other studies have also reported the induction of oxidative stress orchestrated by sodium arsenite which are consistent with the findings from this study [
34].
Treatment with ELEIG (concomitant and post-treatment), produced significant increases in the levels of SOD and GPx in dose-dependent manner, and significant decreases in CAT and MDA concentrations in dose-dependent manner, when compared with group 2 administered sodium arsenite only. However, the significant decreases in CAT concentrations after post treatment with the extract were not dose-dependent. The significant decreases in CAT concentration by ELEIG, indicates an alleviation of oxidative damage by sodium arsenite which had led to induction of CAT level as an adaptive response. This connotes that the ethanol leaf extract could be ameliorative and curative. Administration of ELEIG alone at various doses also produced similar results for the oxidative stress biomarkers with that of the control group. It is therefore possible that the ethanol leaf extract mitigated sodium arsenite-induced toxicity / oxidative stress by enhancing the antioxidant defense systems in the treated rats, thereby enhancing the mopping up of the ROS generated. This may be due to the constituent antioxidant phytochemicals present in the extract. This is corroborated by the findings of Gbadegesin et al. [
13].
There were no visible lesions in the liver tissues of the control group animals, following histological assessment. On the contrary, oral intoxication with sodium arsenite (group 2) caused severe vascular ulceration, portal congestion, infiltrates of inflammatory cells (portal hepatitis), and severe micro vesicular steatosis in the liver. Treatment with graded doses of ELEIG (concomitant and post-treatment), achieved dose-dependent ameliorative and therapeutic effects. Thus, the ethanol leaf extract proved effective in attenuating the sodium arsenite-induced steatohepatitis in the liver of the experimental animals. This is consistent with findings of Gbadegesin and co-workers [
13].
Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.