Details of material procured are as follows. All other chemicals are of standard analytical grade. i) Naringin (cat. no N0073; Tokyo Chemical Industry Co. Ltd.); and ii) Sodium fluoride (cas no. 7681-49-4; EMPLURA^®; Merck KGaA).

After obtaining approval from the Institutional Animal Ethics Committee, Kasturba Medical College, Manipal (approval no. IAEC/KMC/55/2018; dated, 28.07.2018) Manipal, rats were obtained from the central animal research facility (CARF; Manipal, India), and were kept in a 12:12 h light:dark cycle at room temperature and at a humidity of ~81%. A total of 72 adult male Wistar rats, ~90 days old and weighing between 150 to 240 g were used. Food and water was provided ad libitum to all animals. Two separate experiments were conducted.

The first experiment was conducted to determine the concentration of fluoride, among 10 and 50 ppm that could induce behavioural and memory deficits in short duration. For this experiment, 24 animals were divided into three groups: i) Normal (NOR) group; ii) sodium fluoride 10 ppm (FLU10) group; and iii) sodium fluoride 50 ppm (FLU50) group. The NOR group received normal tap water with ~0.5 ppm fluoride for 6 months, while the FLU10 and FLU50 groups received drinking water ad libitum with sodium fluoride at 10 and 50 ppm, respectively, for 6 months. Subsequently, each group of animals consisted of eight rats and behavioural studies such as the forced swim test (FST), novel object recognition test (NORT) and open field test (OFT) were conducted in all groups at the end of 15, 30, 60, 90 and 180 days.

The second experiment, which aimed to elucidate the effect of Naringin against sodium fluoride-induced behavioural and memory deficits, consisted of eight groups, with 8 animals in each group. i) NOR; ii) sodium fluoride 10 ppm (FLU10); iii) FLU10 + Naringin 100 mg/kg bw (FLU10NAR100); iv) FLU10 + Naringin 50 mg/kg bw (FLU10NAR50); v) Naringin 100 mg/kg bw (NAR100); vi) Naringin 50 mg/kg bw (NAR50); vii) prophylactic Naringin 100 mg/kg bw + FLU10 (PRONAR100); and viii) prophylactic Naringin 50 mg/kg bw + FLU10 (PRONAR50).

The Wistar rats of the NOR group were provided with water sourced from normal tap water containing ~0.5 ppm FLU ad libitum. The FLU10 group received water with 10 ppm FLU. For the FLU10NAR100 and FLU10NAR50 groups, Wistar rats were provided drinking water containing 10 ppm FLU ad libitum along with Naringin 100 and 50 mg/kg bw (MilliporeSigma), respectively given per oral gavage. The NAR100 and NAR50 groups were given Naringin 100 and 50 mg/kg bw per oral gavage, along with normal tap water. The PRONAR100 and PRONAR50 groups received Naringin 100 and 50 mg/kg bw for the first 15 days and then subsequently received sodium fluoride 10 ppm for 60 days (a total of 75 days). After the treatment, all animals were subjected to behavioural tests such as the OFT, FST and NORT. The rats were then euthanized with an excess of intraperitoneal pentobarbital injection (200 mg/kg or 5 times the dose required to induce general anaesthesia) to minimize the pain and discomfort of the rodents. There were no observed behavioural or physical characteristics in rats indicating poor health and none of the rats were required to be euthanised before the study was completed. After euthanasia, the brain was removed, fixed in 10% formalin solution at room temperature for 24 h and subsequently the sections of hippocampus and prefrontal cortex were removed and processed for Cresyl violet staining. Reduced glutathione (GSH), lipid peroxidation (LPO), catalase and AChE levels were estimated in the cerebral hemisphere of the brain. The results of behavioural tests, biochemical tests and neuronal count in the hippocampus and prefrontal area were analysed.

The OFT was conducted according to Bures et al (14) in a rectangular wooden box measuring 100x100 cm floor with 40-cm-high walls. A total of 36 equal squares were drawn on the floor of the apparatus (15). The animals were placed in the apparatus and were observed for 5 min. The total number of peripheral and central squares entered by the rat during these 5 min were recorded. The rat was considered to have entered a given square in case it entered that square with all four paws. After 5 min of exploration, the animal was sent back to its home cage. The floor was thoroughly cleaned after each test with a 75% ethanol solution. The number of lines crossed, number of central squares entered, central square duration, freezing time in sec, number of grooming and rearing times were noted, and further statistical analysis was performed.

NORT was performed according to Antunes and Biala 2012(16) in the apparatus consisting of a box of 40x 40x40 cm dimension. On the first and second days of the habituation phase, the rats were kept in the box for 10 min for acclimatization to the manipulations and environment. The training phase was on the third day, in which two identical objects were placed in the boxes and rats were allowed to explore for 10 min. The fourth day was the testing phase, and the same procedure was followed as earlier, except that one of the old objects was replaced with a new different novel object. After each test, the objects and the apparatus were thoroughly cleaned with a 75% ethanol solution. The test phase was conducted 24 h after the familiarization phase to test the long-term memory. Time spent exploring the novel and familiar object was noted, the discrimination index and recognition index were calculated and further statistical analysis was performed. Animals that spent more time exploring or observing the novel object are considered to have normal memory, whereas animals that spend excess time exploring the familiar object as compared with the novel object indicated a memory deficit.

To evaluate the depression-like behaviour of rats, the FST test was performed according to Yankelevitch-Yahav et al (17). A transparent cylindrical glass container with a diameter of 20 cm and a height of 50 cm was loaded with tap water at a temperature of 23±1˚C, in such a way that rats were unable to touch the container's bottom with their legs. Initially, a training procedure was performed in which the rat was placed in a cylinder filled with water for 15 min. After 24 h, the same procedure was repeated, but for only 5 min, during which the behaviour of rats was observed and the movements were categorized into three groups: i) Immobile: Except for those necessary movements to keep its nose above water, the rat had no movement and floated; ii) struggling or climbing: The front paws moved quickly enough to break the surface of the water; and iii) swimming: Limb movement was observed in the form of paddling. The mean time for each behavioural category was measured and analysed. The water was changed after every session.

Biochemical tests were conducted in the second experiment. After euthanasia, one of the two cerebral hemispheres of the brain were removed quickly and homogenized for 20 min with 0.1 M phosphate-buffered saline with pH 7.4, containing 0.1 mM EDTA at room temperature and stored at -80˚C for biochemical analysis procedures. The homogenates obtained were centrifuged at 4˚C at a rate of 14,000 x g for 30 min and the resultant supernatants were collected for analysis as follows.

This method employed an optimized enzymatic GSH reductase recycling procedure for the assessment of GSH. To remove protein, 100 µl of brain homogenate was mixed with 100 µl of metaphosphoric acid at room temperature for 10 min and centrifuged with 2,000 x g for 2 min at 4˚C. To increase the pH, 50 µl of 4 M triethanolamine was mixed with each ml of homogenate. To perform the total GSH assay, a sample of 50 µl was added to 150 µl of a reaction mixture having 0.24 mM NADPH, 2 mM EDTA, 0.1 mM 5,5'-dithiobis-2-nitrobenzoic acid, 0.4 M 2-(N-morpholino) ethane-sulfonic acid, 0.1-unit glutathione reductase and 0.1 M phosphate (pH 6.0). The absorbance at 412 nm was used to determine total glutathione (18).

Brain homogenate of 100 µl was added to 100 µl of saturated methanol (95%) and 1 ml of cold chloroform at 4˚C and mixed thoroughly. LPO was extracted from the chloroform layer after being centrifuged at 2,000 x g for 5 min at 4˚C. Then, 500 µl of chloroform extract was added with chloroform-methanol solvent 450 µl and chromogen 50 µl in a glass tube. After 5 min of incubation at 4˚C, absorbance at 500 nm was measured. Later, LPO was expressed as nmol/g tissue after each of the homogenates was assessed in duplicates (18).

Catalase activity was estimated by measuring hydrogen peroxide reduction at 240 nm in a reaction medium having 20 mM H₂O₂ obtained from MilliporeSigma, 10 mM potassium phosphate buffer at pH 7.0 and 0.1% Triton X-100 (MilliporeSigma). One catalase unit is defined as 1 µmol of H₂O₂ consumed per min expressed as units/mg protein (19).

The estimation of AChE activity was performed using Ellman's method (20). In a cuvette, an aliquot of 0.4 ml of homogenate was mixed with 2.6 ml of 0.1 M phosphate buffer at pH 8 and 100 µl of 5, 5'-dithio-bis-(2-nitrobenzoic acid). The contents of the cuvette were mixed with bubbling air, and the absorbance at 412 nm was measured using a LKB spectrophotometer. The basal reading was recorded when the absorbance remained stable. To determine the change in absorbance per minute, 20 µl of acetylthiocholine was added and absorbance change was recorded at intervals of 2 min for a period of 10 min (20).

Histological tests were performed on animals in the second experiment. After euthanasia, the brain was preserved in 10% formalin for 24 h at room temperature. The whole brain was cut coronally 2-4 mm anterior to the midpoint measured from the anterior to the posterior pole of the rat brain for taking sections passing through the hippocampus. For the medial prefrontal cortex, a selected area of the cerebrum was isolated from the other parts of the brain by separating 3/8 of the cerebrum's front parts (21). These cut parts of the brain were used to make a block from which 5-6 mm thick coronal sections were taken and processed for Cresyl violet staining (22). Images were captured from the CA3 area of the dorsal hippocampus and medial prefrontal cortex of each rat brain section were taken at 40X magnifications using a ProgRes CapturePro 2.1, Jenoptik microscopic camera (Jenoptik AG) fitted with an inverted phase contrast light microscope. Numerical quantification of viable/surviving (number of viable neurons/total number of neurons x100) and degenerated CA3 neurons (number of degenerated neurons/total number of neurons x100) in the region of the hippocampus and prefrontal cortex was performed.

All data obtained are presented as mean ± SEM. GraphPad Prism 8 software (GraphPad Software, Inc.; Dotmatics) was used to analyse the data. All the parameters were checked for normality using the Kolmogorov-Smirnov test and all the data was distributed normally. A one-way ANOVA test followed by Tukey's multiple comparison test was performed to compare between groups. P<0.05 was considered to indicate a statistically significant difference.

Numerical quantification of viable and degenerated neurons in the region of the prefrontal cortex and CA3 hippocampus was performed. The mean for each group was presented as percent (%). Mean percent values of viable and degenerated neurons of each group with ± SEM were checked for normal distribution using the Kolmogorov-Smirnov test and one-way ANOVA was performed. Tukey's multiple comparison test was used for comparison between groups. P<0.05 was considered to indicate a statistically significant difference.

In the first experiment, the data regarding the behavioural tests of OFT, NORT and FST were analysed at the end of 60 days are shown in Fig. 1.

After 60 days, behavioural tests revealed significant (P<0.05) changes in the rearing aspect of OFT in the FLU10 (0.5±0.3780) and FLU50 (1.714±0.6442) groups compared with the NOR group (4.750±1.264). There was a decrease in the number of lines crossed in both the FLU10 (49.75±4.131) and FLU50 groups (53.71±4.173) compared with the NOR group (65.00±7.919), but this was not statistically significant (Fig. 1).

The FLU10 group had statistically significant changes in the discrimination index (DI) (0.07875±0.06443) and recognition index (RI) (0.4563±0.03278) of the NORT compared with the NOR group, with DI 0.1238±0.04342 and RI 0.5613±0.02133, respectively. The FLU50 group showed increased floating time (48.29±5.656) and reduced struggling time (28.71±2.146), while the FLU10 group showed reduced struggling time (30.88±0.6105) as compared with the NOR group floating time of 28.14±2.005 and struggling time of 37.43±2.369, respectively, with statistical significance (P<0.05) as seen in Fig. 1.

Although similar and enhanced changes were observed in FLU50 group, the present study selected the FLU10 group at the end of 60 days for the second experiment, as this was the concentration and duration that could induce significant behavioural changes along with memory deficits.

From the above results of the first experiment, the FLU10 group with a 60-day duration was selected for the second experiment to explore the protective and ameliorative effects of Naringin 50 and 100 mg/kg bw on sodium fluoride-induced behavioural changes.

An OFT was conducted, and the results were analysed. Parameters such as lines crossed, central square entry, central square duration, freezing time, rearing and grooming were analysed between the groups. In FLU10 group, there was decrease in the number of lines crossed (54.00±7.26), number of central square entry (3.5±0.84) and central square duration (5.0±1.48) as compared with other groups, but was statistically not significant. Rearing (5.0±1.06), grooming (1.41±0.94) and freezing (3.5±0.84) in FLU10 group did not show statistically significant changes as compared to other groups.

In this test, the Recognition Index (RI) and Discrimination Index (DI) of the Novel object recognition test (NORT) for the FLU10 group were 0.39±0.01 and -0.21±0.03 respectively, which was statistically significant as compared with all other groups except the PRONAR100 and PRONAR50 groups.

The RI and DI showed statistically significant changes between the FLU10 and NOR groups, and the FLU10NAR100 and FLU10NAR50 groups compared with FLU10, suggesting that the memory deficit induced by sodium fluoride at 10 ppm was ameliorated by the treatment group of FLU10NAR100 as well as the FLU10NAR50 group. The NAR100 and NAR50 groups also showed statistically significant enhanced memory as compared with the FLU10 group. However, the PRONAR100 and PRONAR50 groups, even after marginal improvement in RI and DI failed to show a statistically significant difference as compared with FLU10 as shown in Fig. 2.

In the FST the struggling time for the FLU10 group was 61.17±9.71 sec, which was the lowest struggling time as compared to all other groups. The floating time was 99.83±11.65 sec, which was the highest floating time as compared with all other groups, and floating time was increased and struggling time was decreased in FLU10 group with statistically significant changes as compared with all other groups as shown in Fig. 3. This suggested that the stress and depression induced by FLU10 was ameliorated by the treatment group of the FLU10NAR100 and FLU10NAR50 groups, along with the PRONAR100 and PRONAR50 prophylactic groups (Fig. 3).

LPO in the NOR group was 346.3±6.38 nm/mg of protein, which was statistically significant compared with that of the FLU10 group at 1,104±1.46 nm/mg of protein (P<0.05). The combination of Naringin 50 and 100 mg/kg bw with sodium fluoride 10 ppm (FLU10NAR 50 and FLU10NAR100 groups, respectively) showed 244.6±2.10 and 297.8±3.49 nm/mg of protein LPO, respectively; this indicated a significant reduction in LPO compared with the FLU10 group. Other groups, such as NAR50, NAR100, PRONAR50 and PRONAR100 also showed a signification reduction in LPO compared with the FLU10 group. All groups showed a significant change of P<0.05 as compared with the FLU10 group (Fig. 4).

The catalase activity of the FLU10 group was 20.12±2.67 µmol of H₂O₂ decomposed/mg of protein, which showed significant (P<0.05) changes as compared with the NOR (68.31±8.72), NAR50 (64.51±5.57), NAR100 (74.17±6.41), PRONAR50 (68.67±8.27) and PRONAR100 (89.20±2.34) groups. Catalase activity was increased in the FLU10NAR50 (33.49±4.27) and FLU10NAR100 (40.36±7.13) groups compared with the FLU10 group but was statistically insignificant, as seen in Fig. 4.

GSH of the FLU10 group was 26.54±1.70 nm/mg of protein, which was lower compared with the NOR group (39.12±7.80), as well as to all other groups such as NAR50 (32.88±2.00), NAR100 (33.38±1.07), FLU10NAR50 (33.26±2.11), FLU10NAR100 (35.72±2.21), PRONAR50 (32.60±1.87), PRONAR100 (37.58±1.54), but it was statistically insignificant as seen in Fig. 5.

AChE of NOR group was 0.001202±0.0003 (micromoles of acetylcholine iodide hydrolysed/mg of protein), FLU10 (0.0007015±0.05), NAR50 (0.0008399±0.06), NAR100 (0.001042±0.04), FLU10NAR50 (0.0009300±0.08), FLU10NAR100 (0.0009822±0.07), PRONAR50 (0.0009677±0.10), PRONAR100 (0.001001±0.03). These levels were not statistically significant with normal as well as fluoride groups as seen in Fig. 5.

In the hippocampus CA3 region, the viable neuronal count percent of the FLU10 group was (52.85±01.25), which was significantly reduced (P<0.05) compared with the viable neuron count of NAR100 group (61.53±01.45). The NOR group had 59.5% viable neurons, which was increased compared with the FLU10 group, but not statistically significant. The treatment groups of FLU10NAR100 (58.50±01.64) and FLU10NAR50 (57.11±01.88) did not appear to have any statistically significant changes as compared with the FLU10 group (Fig. 6).

The FLU10 (47.14±01.23) group had a significantly (P<0.05) higher percentage of degenerated neurons compared with the NAR100 (38.46±02.01) group. The treatment groups of degenerated FLU10NAR100 (41.50±01.76) and FLU10NAR50 (42.88±03.19) did not appear to have any significant changes as compared with the degenerated FLU10 group. However, in both viable and degenerated neuron counts, there was no statistical significance between NOR and FLU10 (Fig. 6).

In the prefrontal region, the viable neuron count percent of the FLU10 group (51.50±01.31) was significantly (P<0.05) reduced compared with the NAR100 (60.66±01.85) and NAR50 groups (59.33±01.66). The treatment groups of FLU10NAR100 (54.00±02.17) and FLU10NAR50 (57.11±01.88) were not significantly changed compared with the FLU10 group (Fig. 7).

The FLU10 group had an increased number of degenerated neurons percent (48.50±01.31) compared with the NAR100 (39.33±01.25) and NAR50 groups (40.67±01.40) with a statistical significance of P<0.05. The treatment groups of FLU10NAR100 (46.00±01.31) and FLU10NAR50 (44.00±02.12) did not have any statistically significant changes compared with the FLU10 group (Fig. 7).