ABSTRACT
Objectives:
Vanillic acid (VA) is a flavoring agent, a phenolic acid, and an intermediary by-product formed during transformation of ferulic acid to vanillin. It has been investigated for diverse pharmacological actions and used in Chinese medicine for decades. However, there is no information in the literature about its mechanism of toxicity or safety with long-term use. The present study will not only supply information on its pharmacological profile but also encourage evidence-based pharmacotherapeutic use. Hence, we performed a subacute toxicity study.
Materials and Methods:
According to the Organisation for Economic Co-operation and Development Test Guideline 407 (2008), 3 groups of rats were formed consisting of 12 rats (6 male and 6 female) in each group. For the subacute toxicity, the dose was chosen after a limit test was conducted. VA (1000 mg/kg/day) was orally administered for 2 weeks to the treatment group, whereas the control group received an equivalent volume of the vehicle. To assess reversibility, VA (1000 mg/kg/day, p.o.) was administered to the satellite group for 2 weeks and animals were observed for an additional 2 weeks after treatment. The adverse signs, variation in body weight, and mortality were evaluated throughout the study period. On days 15 and 29, blood was collected to evaluate essential biochemical and hematological parameters. The animals were subsequently weighed and sacrificed. The weights of internal organs were recorded; gross necroscopy and histopathological studies were performed.
Results:
The hematological parameters of the satellite group increased and the serum sodium level decreased after the treatment. Satellite groups showed no other major change in biochemical parameters when compared to the control group. In addition, relative organ weights, gross necropsy examinations and histopathological structure of the internal organs showed no major alterations.
Conclusion:
VA showed no adverse effect on the process of leukopoiesis, erythropoiesis or on internal organs, as verified by hematological and biochemical evaluations, gross necropsy, and histopathological studies. The decrease in serum sodium is not considered as a major toxic effect.
INTRODUCTION
Vanillic acid (VA) (4-hydroxy-3-methoxybenzoic acid) is a frequently utilized flavoring agent and an oxidized form of vanillin. It is an intermediary by-product formed during transformation of ferulic acid to vanillin.1,2 It is present in large amounts in the roots of Angelica sinensis,3 fruits of Euterpe oleracea,4 wine, and vinegar5 and has been used in Chinese medicine for decades.6 It was investigated for diverse pharmacological actions in experimental animals and proved to have antidiabetic activity,7,8 an anti-inflammatory effect,9,10 a strong antioxidant effect,11,12 cardioprotectivity,13,14,15 thermal tolerance,16 and inhibitory effects on Neuro-2A cells.17 In addition, it ameliorates glomerulonephritis,18 has a cognitive effect in diabetic mice,19 and its presence was reported in cerebrospinal fluid.20 It was reported to inhibit carbonic anhydrase isozyme III21 and snake venom 5’-nucleotides.22 It controls transgene expression in mammalian cells and mice.23 It showed a protective effect on ulcerative colitis24 and liver toxicity25 and has a proved analeptic effect.26 Furthermore, it acts as an antifilarial agent27 and respiratory stimulant.28
In the mid 20th century, clinical studies were conducted on excretion of VA in urine. In one study, VA was reported as a metabolic product of 4-hydroxy-3-methoxyphenylglycol and 4-hydroxy-3-methoxymandelic acid.29 It was reported as a metabolite of protocatechuic acid, which is stable at alkaline pH of urine.30 In addition, excretory studies were reported in healthy volunteers, patients with circulatory and liver disorders, and smokers and nonsmokers and during stress.31,32,33
VA is supposed to be administered for long durations to treat chronic disorders; therefore, assessment of its safety or the risk of occurrence of toxic effects becomes crucial. Current scientific research studies revealed undesirable effects of various plant extracts and phytochemicals in rodents at higher dosages, for instance neurotoxicity (Cannabis sativa, Papaver somniferum, and Erythroxylum spp.), hepatotoxicity (Cimicifuga racemosa, etc.), genotoxicity (thymol and carvacrol), carcinogenicity (capsaicin, chili powder, safrole), cytotoxicity (Withania somnifera, safrole-2’, 3’-oxide, etc.), nephrotoxicity (aristolochic acid, turmeric, etc.), teratogenicity (pyrrolizidine alkaloid monster, heliotrine), and gastrointestinal effects (red pepper, fennel, etc.).34 Brown35 discussed case studies of 12 dietary supplements and 21 herbs that give rise to a possible risk of hepatic injuries in certain individuals. These reports are alarming and compelling researchers to assess the safety of phytochemicals in long-term use. Toxicological studies on phytochemicals not only enrich the ethnopharmacology but also augment the careful utilization of phytochemicals and prevent undesirable effects, which seem to be a prime hurdle for the long-term use of modern medications.36 As per the Organisation for Economic Co-operation and Development (OECD) TG 407 (2008),37 subacute toxicity studies are usually planned and performed after getting early details in acute toxicity studies. It improves understanding of the probable untoward effect on health likely to occur from continuous utilization of medicines over a short period and is considered a foundation for conducting subchronic and chronic toxicological studies.38 Additionally, subacute toxicology studies in experimental animals are thought to be a mandatory stage to start with for clinical trials and thereafter marketing of drug molecules.39
Acute toxicity studies on VA are reported in the literature and the LD50 value was reported as 5020 mg/kg i.p. in rats and 2691 mg/kg i.p. in mice.40,41,42 However, the currently available scientific literature does not contain enough data on subacute toxicity studies of VA. Hence, it was decided to perform a subacute toxicity study to determine the toxic effect (if any) of VA on physiological processes (such as erythropoiesis and leukopoiesis) and vital internal organs in rodents.
MATERIALS AND METHODS
Chemicals
VA (HSN-29189900) was procured from Sigma (St. Louis, MO, USA). Biochemical kits were purchased from Transasia Bio-Medicals Ltd. and Lab-Care Diagnostics (India) Pvt Ltd. All chemicals and biochemical kits were of analytical grade.
Experimental animals
Wistar albino rats of both sexes were procured from the National Institute of Bioscience, Pune. They were kept in propylene cages and room temperature of 22±1°C was maintained with alternate light and dark cycles. All the rats were allowed to eat high quality pelleted food and drink water ad libitum. The Institutional Animal Ethics Committee of AIKTC’s, School of Pharmacy, Navi Mumbai, India approved all the experimental protocols.
Limit test
As per the OECD TG 407 (2008),37 this test was carried out by administrating one dose of VA (2000 mg/kg) to Wistar rats to make a decision about the dose of the subacute toxicity study. The animals were critically examined for any morbidity as well as mortality.
Subacute toxicity
As per the OECD TG 407 (2008),37 3 groups of rats were prepared consisting of 12 rats (6 female and 6 male) in each. The VA (1000 mg/kg/day) was orally administered for 2 weeks to the treatment group, whereas an identical volume of vehicle was given to the control group. To check reversibility, the satellite group was orally administered VA (1000 mg/kg/day) for 2 weeks and then kept for a further 2 weeks after treatment for observation. The toxic signs, body weight changes, water consumption, food intake, and mortality were recorded on a weekly basis. On day 15 the rats in the control and treatment groups were exposed to isoflurane for producing an anesthetic effect and blood samples were collected in tubes coated with ethylenediaminetetraacetic acid to determine the complete blood count, which includes hemoglobin (HGB) count, white blood cell (WBC) and red blood cell (RBC) count, etc. For the other biochemical estimations nonheparinized blood samples were collected. Thereafter, all rats were sacrificed and their internal vital organs were dissected for measuring organ weight and to carry out gross anatomical studies. All isolated organs were stored in 10% buffered formaldehyde to carry out histopathological examinations.
Statistical analysis
GraphPad InStat version 3.0 (GraphPad, San Diego, CA, USA) was used to analyze the data. One-Way ANOVA was applied followed by Dunnett’s multiple range test. The results were expressed as mean ± standard deviation and p<0.05 was considered statistically significant.
RESULTS
Limit test
No mortality or signs of toxic effects were observed; hence as per the guideline of OECD 407 (2008), 1000 mg/kg dose was selected for the subacute toxicity study.
Clinical examination, food and water consumption, and body weight
The treatment and satellite groups did not show any signs of toxicity or mortality within the study period. Usual increases in body weights and food and water consumption were observed in the treatment and satellite groups in comparison with the rats in the control group.
Hematological evaluations
Tables 1 and 2 contain the findings of the hematological evaluations. The treatment group showed normal rises in RBC count, HGB, platelet (PLT) count, mean cell hemoglobin (MCH), MCH concentration (MCHC), packed cell volume (PCV), and mean corpuscular cell volume (MCV) in both sexes of Wistar rats but significant increases in all hematological parameters were recorded in the satellite group rats. In addition, the WBC counts of rats in the treatment and satellite groups were within the reference range and were insignificantly different compared to those of the normal control group although the neutrophil count was slightly increased in male rats in the treatment group, which was reversed after 2 weeks in the satellite group (Table 2). The eosinophil, monocyte, and lymphocyte counts in the treated and satellite groups showed no remarkable change in comparison with the rats in the normal control group.
Blood biochemistry
The findings of the clinical biochemistry analysis are shown in Table 3. It involves estimation of lactate dehydrogenase (LDH), total protein (TP), creatinine (CR), total bilirubin (TB), direct bilirubin (DB), blood glucose (BG), serum glutamic-oxaloacetic transaminase (SGOT), serum glutamine-pyruvic transaminase (SGPT), albumin (ALB), electrolytes [potassium (K), calcium (Ca), chloride (Cl), and phosphate (P)], blood urea nitrogen (BUN), alkaline phosphatase (ALP), and lipid profile [triglycerides (TGs), total cholesterol (TC), and high density lipoprotein (HDL)]. Application of VA to the treatment group rats caused no shift in biochemical parameters in comparison with the normal control rats except for statistically significant decreased sodium levels in the male treatment group, which did not recover in the satellite group to normal levels.
Relative organ weight, gross necropsy, and histopathological findings
Table 4 shows the effect of VA on relative internal organ weight. No significant variation was observed in relative organ weights of the treatment and satellite groups in comparison with the normal control group, although the liver weight of treated rats (male) was high in comparison to that of normal control rats, but it was reversed in the respective satellite group. Gross anatomical examination of vital organs and/or systems of rats in the treatment and satellite groups did not show any major irregularities in comparison to normal control group rats.
Microscopically, normal histomorphological structures with intact length of nerve fibers and normal cellular details were observed in tissue sections of the sciatic nerve. Sections of the brain showed intact supporting matrix and normal histomorphological structures of neurons. Heart sections of the treatment group revealed no changes in the structures of cardiac muscle fiber, and cardiac fibers were found to be organized in a compact and dense manner, having normal nuclei and cell striation with intact length. Renal tissue slices revealed no major structural alteration in renal tubules and glomeruli. Liver tissue showed normal structures of hepatocytes, central veins, and portal triads in intact hepatic parenchyma. Hepatocytes had normal intact nuclei and cellular borders and were arranged as cords. Histopathological sections did not show any inflammatory or metabolic changes. Representative sections of the histological studies are shown in Figure 1.
DISCUSSION
VA is a flavoring agent and found to have diverse pharmacological actions.7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28 The safety of VA in future use may be a major concern specifically to make a decision about the optimum dose and to avoid untoward effects, but such information is lacking in the present scientific literature. A subacute toxicity study is preliminary to a chronic study.37,43 In addition, the results of the present study will not only enrich the pharmacological profile of VA but also encourage evidence-based pharmacotherapeutic use. In the light of these facts, we conducted a subacute toxicity study. Initially, a limit test was carried out, which helped us to make a decision about the dose of VA for the subacute toxicity study by oral administration of one dose of 2000 mg/kg. Rats showed no signs of toxicity or mortality. Hence, it can be concluded that VA (1000 mg/kg b.w.) could be safe for use in a subacute toxicity study.
The study was designed by referring to OECD TG 407 (2008).37 All essential examinations were included in the study, such as daily observation for toxic signs, mortality, measurement of weights, water intake, food consumption, all hematological and biochemical estimations within the blood, gross necropsy, and histopathological studies of the vital internal organs. However, we would like to declare that not all examination mentioned in OECD TG 407 were included in the study (such as urine analysis, estimation of T3, T4, TSH hormone, and cholinesterase).
Clinical observation for toxic signs, food and water consumption, and body weight measurements helped us to monitor progression from covert toxicity to overt signs. If the rat is not in a state of well-being it will not consume enough food or drink the necessary quantity of water. Therefore, clinical observation, food and water intake, and body weights are the indicators of general health and relative organ weight indicates organ toxicity, which may be revealed by hypertrophy and/or hyperplasia. Hence, these evaluations are pivotal in subacute toxicity studies.43,44,45 Rats in the treatment and satellite groups received VA (1000 mg/kg/day) orally for 2 weeks and they were monitored daily during the dosing period for any mortality or signs of toxicity like physiological activities (e.g., pilomotor reflex, abnormal breathing pattern, pupil size, lacrimation), abnormalities of the skin, mucous membranes, fur, and eyes, and occurrence of secretions. Postural changes and reactions to gait and handling were monitored along with the presence of activities (e.g., immoderate grooming, continuous circling) or strange actions and clonic/tonic movements.37 The treatment and satellite groups did not show any signs of toxicity or mortality within the course of the study period in comparison with the normal control group. In addition, the treatment and satellite groups showed a normal increment in body weight, water consumption, and food intake. Table 4 shows the effect of VA on relative internal organ weight. The liver weight of treated rats (male) was high in comparison to the normal control rats, but it was reversed in the respective satellite group. Increase in liver weight was considered an adaptive and nonadverse reaction.46 Other internal organs in the treatment group did not manifest any remarkable impact on internal organ weight.
Biochemical estimations in the blood and hematological evaluations are important indicators in finding out the mechanism of toxic effects47,48,49 and the parameters were selected not only to detect target organ toxicity but also to detect pretoxic changes that might predict impending toxicity.38,43 The results are shown in Tables 1, 2, 3. The RBC, PCV, HGB, MCH, MCV, MCHC, and PLT counts of male and female rats in the treatment group did not reveal any remarkable increase when compared with the normal control group. Significant increases in all the hematological parameters were observed in rats in the satellite group, which were within the reference range, and this cannot be regarded as an undesirable effect of VA.50 This can be justified by considering the contrasting situation of the decline in the RBC and HGB counts and other hematological evaluations, which confirmed anemic condition and untoward impact on functioning of erythropoietic stem cells. In addition, the WBC counts of rats in the treatment and satellite groups were within the reference range and had no remarkable difference when compared with the normal control group, although the neutrophil count was slightly increased in the satellite group in both sexes. This, however, cannot be considered a consequence of infection and inflammation. The eosinophil, monocyte, and lymphocyte counts in the treatment and satellite groups showed no remarkable changes when compared with the normal control group. Therefore, it might be concluded that VA is nontoxic and did not alter the function or efficacy of myeloid tissue.
Table 3 shows the effect of VA on biochemical evaluations. The plasma levels of TP, CR, TB, BG, ALB, electrolytes (K, Ca, Cl, P), BUN, ALP, and lipid profile (TG, TC, and HDL) were unaltered. However, some of the biochemical parameters showed nonsignificant alterations in male and female rats, which included DB, SGOT, SGPT, and Na levels. DB, SGOT, SGPT, and ALB levels are important indicators of liver function.51 In male treated and satellite group rats, an insignificant high level of DB was observed in comparison with the respective control group; even so no major alteration was reported in other liver function tests (SGOT and SGPT). In female rats, DB level was nonsignificantly increased among the treated rats, but reversed within the satellite group with slightly increased SGPT and SGOT levels in the treatment and satellite groups. All the alterations were nonsignificant and not in coordination with the macroscopic and histopathological findings in the liver (Figure 1), conducted to correlate the biochemical findings of the liver.39,43 Furthermore, albumin levels were not significantly altered in female and male rats. On the basis of these findings, it can be concluded that VA does not have any subacute toxic effect on the liver.
The effect of VA on renal function was assessed by estimation of BUN, CR, TP, and LDH levels.52,53 No statistically remarkable change was recorded in the renal functional parameters of male and female rats in the treatment and satellite groups. The above evaluations showed that oral administration of VA may not alter the renal function, which is in concurrence with normal renal macroscopic and histopathological findings (Figure 1) of female and male rats in the satellite and treatment groups.
Electrolytes (K, Na, P, and Ca) in serum were evaluated during subacute toxicity studies.54,55 In our study, P, K, and Ca evaluation did not show any statistically remarkable change within the treatment and satellite groups in comparison with the normal control group. Although a significant decline in Na level was observed in male rats in the treatment and satellite groups, a statistically insignificant high level was reported in female rats in the treatment group in comparison with the normal control group. Based on the available knowledge of electrolyte balance, we can propose the probable mechanism behind reduced serum Na level. Firstly, it could be increased urinary loss and high cellular uptake.56 Secondly, the process may be mediated by antidiuretic hormone and atrial natriuretic peptide.56 However, this might not be viewed as a serious unsafe effect because a Na level below 20 mEq/L can only indicate Na leakage from damaged renal tubules or hypovolemia57 or this effect can be recognized as a side effect as in the case of all classes of antidepressant drugs.58 Repeated administration of VA does not affect the lipid profile of male and female rats. Thus, it is apparent that oral dosing of VA does not influence the electrolyte balance or the process of lipid metabolism.
Gross necropsy and histopathological studies represent the cornerstone within the process of safety evaluation before trials in human patients, essential to find out any relationship and relevance of treatment-related findings.39,43 In our study, the toxic effect on internal vital organs (i.e. brain, heart, liver, kidney, and sciatic nerve) was evaluated by gross necropsy and histopathological studies (Figure 1), which revealed no abnormality in any vital major organs. Thus, the result indicates that the VA is reasonably safe at the selected subacute dose.
CONCLUSION
VA is a polyphenol with diverse pharmacological actions, but no information on subacute toxicity studies is available in the current literature. To enrich its pharmacological profile and encourage its evidence-based pharmacotherapeutic use, a subacute toxicity study was conducted using experimental rats. To summarize, no mortality or clinical toxic signs were recorded during the study period; normal rises in body and internal organ weight were observed. The processes of leukopoiesis, erythropoiesis, and physiology of internal organs were not changed and no structural deformities were detected in the gross necropsy or histopathological studies of vital internal organs. The serum Na level was decreased in male Wistar rats with no major changes in levels of the other electrolytes, and this cannot be categorized as a major toxic effect. Hence, it can be concluded that the VA is safe in experimental rats during subacute toxicity studies. Further subchronic and chronic toxicological research is needed to investigate the safety characteristics of VA.