Antinociceptive and Cytotoxic Effect of Extracts of Croton bonplandianus Leaves
Antinociceptive and Cytotoxic Effect of Extracts of Croton bonplandianus Leaves
Hina Yasin1,2*, Shaukat Mahmud2, Hina Abrar1, Kaneez Fatima3, Rabia Bushra1 and Saima Zahid2
1Dow College of Pharmacy, Dow University of Health Sciences, Ojha Campus, Gulzar-E-Hijri, Scheme-33, Karachi, Pakistan
2Baqai Institute of Pharmaceutical Sciences, Baqai Medical University, Super Highway, Gadap Road, Karachi, Pakistan
3Institute of Pharmaceutical Sciences, Jinnah Sindh Medical University, Rafiqui H.J. Shaheed Road, Karachi, Pakistan
ABSTRACT
Role of phytochemicals and plant based drugs in curtailment of diseases has already been established. Croton bonplandianus plant has found to be popular in the healthcare system for treatment of various complaints. In the present study, plant leaves were screened for analgesic and cytotoxic activities using animal models for the safe and effective utilization of plant material. The leaves were soaked in methanol and successively fractionated using n-hexane, chloroform, ethyl acetate and water. Mentioned biological activities were determined in different groups of wistar strain mice by administering various leaves extracts in differential dose pattern (81, 54 and 27 mg/kg). Cytotoxic activity was assessed by the Brine shrimp bioassay method. Results showed that extracts significantly responded as analgesic drug comparable to standard drug using different methods of evaluation for analgesic activity. Brine shrimp bioassay in different leaves extracts also showed similar effects likewise to the standard drug vincristine sulphate. All extracts exhibited marked cytotoxic activity as well against the Artemia salina (brine shrimp eggs). Based on the findings, it is concluded that the leaves extracts of the C. bonplandianus have potent analgesic and cytotoxic effects but in higher doses only. However; phytochemical screening and isolation of active constituents will need to be explored further to endorse the utilization of the Croton plant clinically for various therapeutic activities.
Article Information
Received 24 March 2022
Revised 20 December 2022
Accepted 11 February 2023
Available online 08 May 2023
(early access)
Published 26 August 2024
Authors’ Contribution
HY and HA presented the concept, conducted experiments and did validation. HY, HA, KF, RB and SZ wrote the manuscript. KF, RB and SZ performed data analysis and compilation, and reviewed of manuscript. SM supervised the research project.
Key words
Extract of leaves of Croton bonplandianus, Analgesic activity, Brine shrimp bioassay, Wistar strain mice, Artemia salina
DOI: https://dx.doi.org/10.17582/journal.pjz/20220324060344
* Corresponding author: hina.yaseen@duhs.edu.pk
0030-9923/2024/0005-2469 $ 9.00/0
Copyright 2024 by the authors. Licensee Zoological Society of Pakistan.
This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
Introduction
Plant based products additionally to food are also being employed as alternative medicine. Various species of plant kingdom are still required for evaluation to establish the therapeutic potential of active constituents (Danish et al., 2020; Feng et al., 2017). It has been documented that more than 200 natural based compounds are prescription medicines widely obtained from higher plants, minerals, fungi and marine sources (Sandberg and Corrigan, 2001; Füllbeck et al., 2006). Compared with modern medicine, therapeutic agents derived from plants stand to be safeowing to fewer side effects (Yasin et al., 2019; Calixto, 2000). Herbal medicines are growing and now currently focused as alternative medicines for preventing and curing different ailments (Grundmann and Yoon, 2014). Herbal plants are the major sources of various secondary metabolites including alkaloids, flavonoids, terpenoids, tannins, providing a significant role in the treatment of different disorders especially against microbial infections (Evans, 2002). Unfortunately, beyond many benefits of natural drugs, the efficacy and potency of medicinally valuable plants are not still discovered. Only a small percentage of plants and their species are exposed for phytochemical and fractionation screening (Malesh and Satish, 2008). Phytochemical components like flavonoids and tannins also reported for antibacterial, antioxidant, anticancer, anti-inflammatory and analgesic activity (Kumar et al., 2008; Jaganath and Crozier, 2010; Malan and Roux, 1979).
The genus Croton of the family Euphorbiaceae is documented to contain approximately 1300 species of the plants distributed in tropical and subtropical areas of the world. Many of Croton species possessed therapeutically valuable moieties. Previous studies have proven the role of Euphorbiaceae family as folk and traditional medicines. These Croton trees, herbs and shrubs are utilized for cardiac diseases, liver complaint, anti-pyretic, anti- inflammatory chest ailments, cancer, diabetes, arthritis and skin infections (Islam et al., 2019; Xu et al., 2018). Croton bonplandianum, is one of the recently identified species, documented to possess remarkable antimicrobial activity and consider to be capable to treat urinary tract infections (Ghosh et al., 2018). Investigations were conducted on C. bonplandianus stem bark for the identification and isolation of therapeutic compounds using standard protocol and analytical methods. Total flavonoids, alkaloids, phenolic contents, saponins and tannins were identified. Vitamins such as ascorbic acid (Vitamin C) and riboflavin (Vitamin B12) were also found to be present in rich quantities (Dutta et al., 2014; Lowry et al., 1951; Athanasiadis and Moral, 2013). Moreover, comprehensive evaluation on stem latex of C. bonplandianus showed anti-microbial and antiseptic responses upon the application on fresh wound (Sriwastava et al., 2010; Qureshi et al., 2012). Phytopharmacological analysis indicated that the leaves of C. bonplandianus significantly exhibited anti-inflammatory activity (Yasin et al., 2021), wound healing effect, owing the existence of antioxidant enzymes and rutin (Divya et al., 2011).
The current study is designed to examine the analgesic and cytotoxic activities of C. bonplandianus plant as limited data is available on this species of the plant. Leaves extracts will be prepared in methanol and then fractionation will be performed using different solvents including n-hexane, chloroform, ethyl acetate and water. For analgesic activity, animals will receive different leaves extracts (methanolic, aqueous and ethyl acetate) in different doses (81, 54 and 27 mg/kg) and so grouped accordingly. Analgesia will be observed on animal models by inhibition of writhing induced by acetic acid, formalin induced paw licking method and hot plate-induced nociceptive activity in mice. Cytotoxic activity of all leaves extracts obtained in (methanolic, n-hexane, chloroform, ethyl acetate and water) will be assessed using reliable technique of Brine Shrimp Bioassay against the Artemia salina (brine shrimp) eggs.
Materials And Methods
Hexane (Sigma-Aldrich), chloroform (Sigma-Aldrich), methanol (Sigma-Aldrich), ethyl acetate (Sigma-Aldrich), distilled water and Whatman filter paper for extraction of plant. Acetyl salicylic acid (ASA) (100mg/kg/body weight), acetic acid (0.8%), formalin (1%), NaCl (0.9%), analgesia meter hot plate (Model EH-01 Orchid Scientific), feeding tubes, distilled water and stopwatch for analgesic activity, Artemia salina Leach. (brine eggs), Sea salt (NaCI), vincristine sulphate, lamp (to attract shrimps), small tank, pipettes (5, 10ml), micropipette (5-50nl and 10-100µl), glass vials, magnifying glass for cytotoxic activity were used for experiments.
Extraction of C. bonplandianus plant
Leaves of C. bonplandianus (Euphorbiaceae) were collected from University of Karachi. The plant was identified during June 2018 by the Department of Botany (Taxonomy), University of Karachi, Pakistan. A voucher specimen no. 03 was deposited in the Department of Pharmacognosy, Baqai Institute of Pharmaceutical Sciences, Baqai Medical University Karachi, Pakistan.
The dried leaves of C. bonplandianus were weighed (5 Kg) and percolated for 15 days in 10 L methanol, percolation was continued till the leaves were practically exhausted (three soaking and percolation cycles). Menstrum was evaporated under reduced pressure (40ppm) and temperature of 40ºC. Fractionation was then carried out for the isolation of active drug components using different solvents including n-hexane, chloroform, ethyl acetate and water. Methanolic (MeOH), ethyl acetate (EtOAc) and aqueous extract (H2O) of C. bonplandianus leaves were selected for determination of analgesic activities to avoid any toxicity (Pereira et al., 2020; Umoh et al., 2020) while all leaves extracts were subjected to evaluate the cytotoxic activity through brine shrimp bioassay. These extracts were administered in doses of 27, 54, 81 mg/kg. Dose protocol was selected on the basis of previously reported studies (Okokon et al., 2006).
Animals for analgesic activity
Male albino mice of either sex (25-30 g) were selected for analgesic activity due to resemblance with human system. Mice were purchased from the animal house of Baqai Institute of Pharmaceutical Sciences (BIPS), Baqai Medical University, Karachi. Albino mice were kept in the standard environment and balance diet with water in animal house for 24 h at 28°C±5 temperature. Analgesic effect was evaluated through acetic acid induce writhing in mice, formalin induce liking and thermal induction by hot plate method.
Induction writhing in mice
Albino mice were kept fasted with access of distilled water for 24 h prior to the treatment. Different leaves extracts of the C. bonplandianus were administered orally to adult albino mice, divided into 11 groups. The control group received only distilled water (10ml/kg) while remaining three groups received MeOH, EtOAC and H2O leaves extracts. These three groups ML (MeOH), AqL (H2O) and EAC (EtOAC) were further categorized in to sub groups (5 mice in each) and treated with doses of 27, 54 and 81mg/kg C. bonplandianus orally. Acetyl salicylic acid (ASA) was administered to the reference group (ASA) in a single dose of 100mg/kg. Acetic acid 0.2 ml (0.8%) was administered intra-peritoneally (i.p.) to all animal groups after 30 min of plant drug administration. Writhing movements (stretching of hind limbs along with contraction of abdominal muscles) were counted for 30 min with 10 min time intervals (Okokon and Nwafor, 2010; Nwafor and Okwuasaba, 2003; Okonkon et al., 2006). Antinociception were displayed as the reduction of the number of writhing movements in all groups.
Induction of paw licking in mice
Formalin induced paw licking method (Ceccarelli et al., 2003; Honda et al., 2000) was used to evaluate the analgesic activity of the extract. Adult albino mice weighed 25-30g of either sex recruited into 11 different groups of 6 mice each were used for the experiment. The animals were pretreated with C. bonplandianus leaves extracts (27, 54 and 81 mg/kg i.p) and ASA (100mg/kg) before administering formalin. 0.1 mi of 1% formalin solution was injected in sub planter region of right paw of mice. In control group 0.1 ml of 0.9% NaCl was injected in sub planter region of left paw of mouse. The licking response, a pain indicator, was observed for 30 min. The first phase of antinociception appeared after 5 min of formalin injection and second phase shown after 15 to 30 min of formalin subcutaneous administration expressing the neurogenic and inflammatory analgesic response (Obese et al., 2021).
Induction of nociceptive activity in mice
Thermal nociceptive response is helpful to determine the central analgesic activity (Shoaib et al., 2017). The effect of different leave extracts of C. bonplandianus on hot plate was investigated in mice. All animal were divided into 11 groups and each group comprised of 6 animals. First group served as control and received normal saline while standard group received ASA 100mg/kg orally. The animals were pretreated with different leave extracts of C. bonplandianus (27, 54 and 81 mg/kg i.p) and ASA (100mg/kg) before placing on hot plate. The mice were placed on hot plate maintained at 55°C±2°C and expression of nociception such as flicking, licking, rearing and jumping on hind limb was observed (Bouali-Benazzouz et al., 2021). The experiment was terminated 25 sec after placement of animal on hot plate to prevent tissue damage.
Brine shrimp lethality assay (BSLA) for C. bonplandianus
Brine shrimp (Atremia salina Leach.) eggs purchased from the local market were allowed to hatch to nauplii in one liter of sea water in a small tank and then transferred into another tank containing diluted fresh seawater (38 g of non-iodized sea salt dissolved in 1 L distilled water for enhancing the visibility of nauplii. Finally, 10 nauplii were separated carefully using micropipette for brine shrimp bioassay.
Each test sample (32 mg) was dissolved in 200μl of 1% DMSO and final volume of 20 ml was made from seawater. The stock solutions having concentration of 1600 μg/ml of each sample were prepared. Serial dilution with seawater of each sample was carried out from the stock solution to obtained 800, 400, 200, 100, 50, 25, 12.5, 6.25 µg/ml extracts. Afterwards, 2.5 ml of each extract was mixed with the seawater (2.5 ml) already containing 10 nauplii for evaluation.
Low concentrations of vincristine sulphate (10, 5, 1, 0.5, 0.25, 0.125 and 0.06 μg/ml) were prepared as positive control. For negative control DMSO (50 µl) added to already marked three of each test tubes having seawater 4.95 ml along with 10 nauphii (Asaduzzaman et al., 2015). All test tubes were examined after 24 h against black background using magnifying glass. Total numbers of lived nauplii were counted and percentage of lethality of brine shrimp nauplii in each test tube was computed.
The lethal concentration (LC) for 50% mortality after 24 h of exposure and the chronic LC50 was determined using the probit method. LC50 values obtained at greater than 800 ppm for plant extracts would not be considered. The extent of lethality was found to be directly proportional to the concentration of the extract. The LC50 (median lethal concentration) values were calculated using the regression line analysis obtained by plotting the drug concentrations at x-axis (independent parameter) and percent death at Y-axis (dependent). LC50 values were measured finally through a probit scale.
Abbot’s expression was used to determine mortality (Abott, 1925).
Pt= [(Po-Pc)/ (100-Pc)] × 100
Where Po is Observed mortality; Pc is control mortality.
Statistical analysis
The quantitative data were presented as mean ± SEM (standard error of mean) and SPSS (social statistical package) version 21 software was used to analyze the results. One way analysis of variance (ANOVA) with post-hoc Tukey HSD was applied to assess the difference among various treatment, standard and control groups. The computation was made at 95% of confidence interval and P < 0.05 was considered to be significant during comparative analysis.
RESULTS
Effect of plant extract writhing in mice
In the present study different leaves extract (MeOH, Aqueous, EtOAC) of the C. bonplandianus (Dose 27, 54 and 81 mg/ kg) were selected to determine the analgesic potential in acetic acid induced writhes in albino mice against standard drug acetyl salicylic acid (ASA, 100 mg/kg). IP administration of acetic acid produces pain sensation in mice characterized by writhing and abdominal contraction. The total numbers of writhes were counted for 30 min with specified time intervals and result was expressed for total number of writhes as mean±SEM (Table I).
All extracts were compared with control group and significant dose dependent reduction was noticed in acetic acid induced stretching of limbs and abdominal contraction. Analgesic activity was observed in all extracts in all doses (27-81 mg/kg) when compared with control group. Significant differences were also shown by lower P-value ranged between 0.05 to 0.001. However, all extracts induced enhanced analgesia in dose dependent manner even better than ASA except ethyl acetate extract (Table I).
Effect of plant extract licking activity mice
Outcomes of formalin induce liking effect against the methanolic, aqueous and ethyl acetate extracts were displayed in Table II. Results were compared with the standard drug. The significant levels were expressed by lower P-value ranged between 0.05 to 0.001. The (MeOH) and aqueous extracts possess significant result in high doses while EtOAC extract showed non- significant results.
Table I. Analgesic activity of different extracts of Croton bonplandianus.
|
Treatment groups |
Number of writhing/ 10 min |
||
|
0-10 min |
10-20 min |
20-30 min |
|
|
Control |
18.66±0.33 |
12 ± 0.55 |
11.33 ± 0.33 |
|
ML-27 |
6.66±0.33** |
6.33 ± 0.33 |
1.66 ± 0.33*** |
|
ML-54 |
6.66±0.33** |
3.33 ± 0.33* |
0.33 ± 0.33*** |
|
ML-81 |
9.66±0.88* |
6.33 ± 0.33** |
2.33 ± 0.33*** |
|
AqL-27 |
10.33±0.33* |
6.66 ± 0.33** |
3.33 ± 0.33** |
|
AqL-54 |
11.66±0.88* |
6.33 ± 0.33* |
5.66 ± 0.33* |
|
AqL-81 |
10.33±0.88* |
5.33 ± 0.33** |
0.33 ± 0.33*** |
|
EAL-27 |
10.33±0.88 |
8.33 ± 0.33* |
5 ±0.57 * |
|
EAL- 54 |
12.66±0.88* |
10.33± 0.33* |
6.66 ± 0.33* |
|
EAL-81 |
5.66±0.33 |
4.33 ± 0.33 |
4.66 ± 0.33 |
|
ASA |
18.66±0.33* |
4.0 ±0.55* |
3.33 ± 0.33** |
Where ML, methanolic leaves extract of C. bonplandianus (81, 54 and 27 mg/kg); Aq L, aqueous leaves extract of C. bonplandianus (81, 54 and 27mg/kg); EAL, ethyl acetate leaves extract of C. bonplandianus (81, 54 and 27 mg/kg); ASA, acetyl salisylic acid (100mg/kg). Data is subjected to one way ANOVA using SPSS version 21 and illustrated as mean ± SEM. Significant at * P < 0.05, ***P < 0.01, ***P < 0.001 when compared to control (n = 6).
Effect of plant extract on nociceptive activity
Table III shows the effect of different leave extract on analgesic activity. Pretreated mice (27, 54, 81 mg/kg) revealed the dose-dependent increase in latency response in methanolic and aqueous extracts while the group that
Table II. Effect of Croton bonplandianus extract on formalin-induced hind paw licking in mice.
|
Treatment groups |
Time intervals (min) |
|||||
|
5 |
10 |
15 |
20 |
25 |
30 |
|
|
Control |
41.56±0.71 |
18.24±0.64 |
15. ± 0.36 |
12.49±0.21 |
9.78±0.22 |
7± 1.05 |
|
ML-27 |
30±0.68 |
10.43±0.18* |
8.49±0.65 * |
7.52±0.17 |
5.38±0.36* |
2.84±0.63 * |
|
ML-54 |
28.02±0.11** |
8.27±0.63* |
7.69±0.31*** |
5.58±0.22** |
4.47±0.07* |
3.94±0.17*** |
|
ML-81 |
21.78±0.04* |
6.21±0.51** |
4.52±0.91*** |
3.24±0.81* |
2.12±0.07** |
2.07±0.61*** |
|
AqL-27 |
28.30±0.85 |
7.59± .47* |
6.14±0.94 * |
5.05±0.08 |
4.87±0.21* |
2.23±0.11 * |
|
AqL-54 |
26.54±0.54* |
6.56±0.13* |
5.07±0.74* |
4.32±0.43* |
3.67±0.04* |
2.25±0.84* |
|
AqL-81 |
23.41±0.71* |
7.63±0.13** |
5.44±0.90*** |
4.44±0.32* |
3.87±0.42** |
2.87±0.21*** |
|
EAL-27 |
34±0.36 |
7.95± 0.21* |
6.54 ±0.25 * |
5.89±0.87 |
4.15± 0.25* |
3.14 ±0.79 * |
|
EAL- 54 |
30.04±0.54* |
8.74 ± 0.18* |
5.81±0.61* |
4.23±0.53* |
4.09±0.27* |
3.41±0.45* |
|
EAL-81 |
25.66±0.71* |
6.11±0.13** |
5.15±0.24*** |
4.54±0.36* |
3.34±0.61** |
3.10±0.41*** |
|
ASA |
8.66±0.23* |
3.40 ±0.15* |
2.93 ± 0.21** |
2.25±0.18** |
1.19±0.1.18** |
0.00 |
For details of treatment groups, see Table I.
Table III. Analgesic activity of Croton bonplandianus determined by hotplate method.
|
Treatment groups |
Mean analgesic activity (time intervals in min) |
||||
|
0 |
30 |
60 |
90 |
120 |
|
|
Control |
7.21±0.42 |
7.21±0.42 |
7.21±0.42 |
7.21±0.42 |
7.21±0.42 |
|
ML-27 |
8.01±0.54 |
10.23±0.74* |
11.11±0.15* |
11.97±0.65** |
12.13±0.91*** |
|
ML-54 |
7.99±0.94 |
9.61±0.21 |
10.70±0.48* |
11.60±0.33*** |
12.65±0.12*** |
|
ML-81 |
8.86±0.62 |
10.82±0.36 |
11.09±0.66* |
12.74±0.11*** |
13.53±0.89*** |
|
AqL-27 |
7.40±0.17 |
9.54±0.27* |
10.61±0.91*** |
10.78±0.21* |
11.80±0.87** |
|
AqL-54 |
8.44±0.65 |
10.14±0.41* |
10.60±0.29* |
11.40±0.92** |
12.08±0.43*** |
|
AqL-81 |
9.50±1.17 |
11.21±0.40* |
11.60±.0.39*** |
12.41±1.73*** |
12.88±0.58** |
|
EAL-27 |
8.00±0.64 |
8.20±1.00 |
8.67±0.63 |
9.02±0.89 |
9.30±0.14 |
|
EAL- 54 |
7.14±0.64 |
8.09±1.30 |
9.20±0.88 |
9.49±1.25 |
9.87±0.56 |
|
EAL-81 |
8.13±0.77 |
8.67±1.24 |
8.24±0.84 |
8.80±0.15 |
9.17±0.82 |
|
ASA |
9.90±0.78 |
10.00±1.02* |
11.60±0.92*** |
12.60±0.92*** |
13.44±0.78*** |
For details of treatment groups, see Table I.
received ethyl acetate extract of C. bonplandianus expressed insignificant response in all doses. Outcomes of all treated group were compared with standard group i.e., ASA (aspirin 100mg/kg) at 0, 30, 60, 90 and 120 min. The significance level expressed in term of P-value ranged between 0.05 to 0.001. The significance level was calculated with respect to the control group. The higher doses of both the extracts showed comparable significant with standard drug.
Literature supports the analgesic potential of alkaloids, flavonoids and phytosteroids including stigmasterols, campesterol and β-sitosterol. C. bonplandianus may contain moderate to high amount of anyone or/and all of these constituents in combination or in free form, possibly contributing towards potent analgesic effects.
Cytotoxicity of plant extract
The hexane fraction of the leaves showed comparatively moderate toxicity with LC50 value of 303.78 μg/ml contrawise, anticancer drug vincristine sulphate displayed LC50 value of 1.974μg/ml. Other extracts exhibited low cytotoxicity to brine shrimp nauplii (Table IV). High toxicity of hexane extract reflects the higher extraction, probably of alkaloidal components. On the basis of findings, cytotoxic potential of all extracts in descending order is as: VS > HL > ML > ChL > MB > EAL > AqL (Asaduzzaman et al., 2015).
Aqueous extract was virtually non-toxic to nauplii as exhibited very low toxicity with LC50 values greater than100μg/ml. On the basis of the mentioned outcomes (Table IV) the plant extracts considered to be safe and non-toxic and may be used as medicine in future after further screening.
DISCUSSION
Naturally isolated compounds such as flavonoids, tannins, alkaloids, steroids and glycosides possess analgesic activity (Sengupta et al., 2012; Khan et al., 2020; Peres et al., 1998). Euphorbiaceous family comprised of almost 66 genera and more than 550 species, majorities of species not only been accepted to be medicine but also utilized to treat variety of diseases globally (Islam et al., 2019b). C. bonplandianus is known to have antimicrobial, antibacterial, antifungal and wound healing potential (Dutta and Chaudhuri, 2018). Examination of the bark extract of C. urucurana showed the analgesic activity due to the presence of different steroids such as campesterol, beta-sitosterol and stigmasiterol showed (Peres et al., 1998). Methanolic leaf extract of C. lobatus possessed significant analgesic and anti-inflammatory activity therefore, plant extract is recommended for the management of pain and inflammatory condition (Anafi et al., 2017).
All the three (methanolic, ethyl acetate and aqueous leaves extracts) preparations of the C. bonplandianus showed significant (p < 0.05-0.001) dose dependent analgesic action compared with control group and standard drug acetyl salicylic acid group as marked reduction in acetic acid induce writhes and abdominal contraction was observed. On the basis of these finding, it is concluded that C. bonplandianus may also be utilized as an analgesic drug. In future fractionation and isolation of pharmacologically effective natural compounds will provide more safer, potent and effective drug in comparison to synthetic products with higher side effects.
Table IV. Brine shrimp bioassay of different extracts of Croton bonplandianus.
|
Test samples |
Concentration (µg/ml) |
Log Conc. |
Probit |
% Mortality |
% corrected mortality |
LC50 (µg/ml) |
|
HL |
12.5 |
1.09691 |
4.16 |
20 |
11.11 |
303.78 |
|
25 |
1.39794 |
4.16 |
20 |
11.11 |
||
|
50 |
1.69897 |
4.48 |
30 |
22.22 |
||
|
100 |
2 |
4.48 |
30 |
22.22 |
||
|
200 |
2.30103 |
5 |
50 |
44.44 |
||
|
400 |
2.6020 |
5 |
50 |
44.44 |
||
|
800 |
20903 |
7.33 |
100 |
100 |
||
|
ChL |
12.5 |
1.09691 |
3.72 |
10 |
0 |
337.23 |
|
25 |
1.39794 |
3.72 |
10 |
0 |
||
|
50 |
1.69897 |
4.16 |
20 |
11.11 |
||
|
100 |
2 |
4.16 |
20 |
11.11 |
||
|
200 |
2.30103 |
5 |
50 |
44.44 |
||
|
400 |
2.60206 |
5.52 |
70 |
66.66 |
||
|
800 |
209030 |
6.28 |
90 |
88.88 |
||
|
EAL |
12.5 |
1.09691 |
3.72 |
10 |
0 |
419.03 |
|
25 |
1.39794 |
4.16 |
20 |
11.11 |
||
|
50 |
1.69897 |
4.48 |
30 |
22.22 |
||
|
100 |
2 |
5 |
50 |
44.44 |
||
|
200 |
2.30103 |
5 |
50 |
44.44 |
||
|
400 |
2.60206 |
5.25 |
60 |
55.55 |
||
|
800 |
2090309 |
5.25 |
60 |
55.55 |
||
|
AqL |
12.5 |
1.09691 |
3.72 |
10 |
0 |
1392.22 |
|
25 |
1.39794 |
3.72 |
10 |
0 |
||
|
50 |
1.69897 |
3.72 |
10 |
0 |
||
|
100 |
2 |
4.16 |
20 |
11.11 |
||
|
200 |
2.30103 |
4.16 |
20 |
11.11 |
||
|
400 |
2.60206 |
4.48 |
30 |
22.22 |
||
|
800 |
209030 |
4.48 |
30 |
22.22 |
||
|
ML |
12.5 |
1.09691 |
4.16 |
20 |
11.11 |
334.91 |
|
25 |
1.39794 |
4.16 |
20 |
11.11 |
||
|
50 |
1.69897 |
4.75 |
30 |
22.22 |
||
|
100 |
2 |
5 |
40 |
33.33 |
||
|
200 |
2.30103 |
5.25 |
60 |
55.55 |
||
|
400 |
2.60206 |
5.84 |
60 |
55.55 |
||
|
800 |
209039 |
7.33 |
70 |
66.66 |
||
|
VS |
0.06 |
-102218 |
3.72 |
10 |
0 |
1.974 |
|
0.125 |
-0.9030 |
4.16 |
20 |
11.11 |
||
|
0.25 |
-0.6020 |
4.48 |
30 |
22.22 |
||
|
0.5 |
-0.3010 |
5 |
50 |
44.44 |
||
|
1 |
0 |
5.52 |
70 |
66.66 |
||
|
5 |
0.69897 |
6.28 |
100 |
100 |
||
|
10 |
1 |
7.33 |
100 |
100 |
Where extracts of leaves of C. bonplandianus i.e HL, hexane fraction; ChL, chloroform fraction; EAL, fraction; AqL, aqueous fraction; ML, methanolic fraction; VS, vincristine.
The outcomes obtained in present investigation showed the different leaves extracts gives positive responses in reduction of writhes induced by acetic acid and marked reduction in paw licking after formalin induction. Correspondingly the pretreated mice with different leaves extract also delayed the reaction time to heat stimulus. Methanolic and aqueous extract displayed dose dependent response while the mice treated with ethyl acetate were shown nonsignif8cant result. As the methanolic and aqueous extracts of this plant also be reported that they produced anti-inflammatory response in rats (Yasin et al., 2021). It has been reported that writhing reflex produced by acetic acid is may be due to activation of chemo sensitive nociceptors. Acetic acid affected an increase vasodilation and permeability of blood vessels (Gong et al., 2019). Neurogenic and inflammatory pain associated with the formalin induction which can be repented by paw licking of the animal (Chatla et al., 2019). Several studies revealed that flavonoids are considered to produce inhibitory response against inflammation. Flavonoids acts as natural antioxidant used to various ailment especially obesity, cancer, gout, diabetes etc. (Nile et al., 2018). The analgesic activity of this plant correlates with paracetamol. As previously reported data proven that the paracetamol inhibit acetic acid induced writhing. Paracetamol showed inhibitory effect on the synthesis of prostaglandin in the brain (Saliba et al., 2017).
Furthermore, the extract may acquire the typical model of the drug that are centrally acting, as shown inhibitory activity for both early and late phases against formalin induce paw licking (John-Africa et al., 2020). Similarity with the drugs like morphine and opioid with the extract may be due to exhibit central action by increasing reaction time to heat. Hence it might be possible that the plant extracts possess the inhibition of release and activity of inflammatory mediators and/or nociceptive fibers (Mehanna et al., 2018).
The alcoholic extract of C. floribundus stem bark exhibited significant antioxidant, anticholinesterase, cytotoxic and antimicrobial activities (Barth et al., 2018). Antimicrobial effect was observed in aqueous and methanolic stem bark extracts of C. megalocarpus against certain microbial strains. Moreover, extracts were found to be safe and free from acute oral toxicity upon administration in Wistar rats. Cytotoxicity of the stem bark extract was also determined by brine shrimp nauplii (Kathare et al., 2021). In the present investigation HL, ChL, EAL, Aq L, and ML were subjected to lethality bioassay (Table I). It was found that upon exposure of different doses, varying degree of lethality was induced. The LC50 was computed through regression analysis by plotting the graph between percentages of nauplii killed against the concentration of extracts. It was observed that the rate of mortality increases gradually with increase in test sample concentration, indicating that the degree of lethality is directly proportional to the concentration from minimum (12.5 µg/ml) to maximum (800µg/ml). Based on LC50 it can be concluded that all plant extracts possess mild to moderate cytotoxic activity. Henceforth, the leaves drug extracts are considered to be safe and non-toxic. Extracts may be used in clinical settings for the treatment of various ailments in future after further screening and isolation.
CONCLUSION
Plants belong to Croton genus of family Euphorbiaceae are utilized as folk and traditional medicines all over the world. Croton bonplandianus is one of the valuable medicinal plant, however little has been explored in biological activities. Leaves extracts of C. bonplandianus possess comparable/ higher analgesic activity in wistar mice. Qualitative analysis revealed the presence of alkaloids, phenols, flavonoids and steroids in plant extracts of C. bonplandianus. Presence of alkaloids and steroids are presumed for the cytotoxic activity of plant (Dey et al., 2019). Flavonoids and phenolic compounds are antioxidant in nature and might be responsible to control the growth of abnormal cells and so also be adjunct in anticancer therapy.
Acknowledgement
The authors acknowledge the Baqai Institute of Pharmaceutical Sciences, Baqai Medical University, 74600 Karachi, Pakistan for providing equipment, animals and instrumentation facilities. The technical assistance, advice and contribution were research follow.
Funding
This research did not receive any specific grant from funding agencies in the public, commercial, or not-for-profit sectors.
IRB approval
This study was conducted in Baqai Institute of Pharmaceutical Sciences, Baqai Medical University, Karachi, Pakistan, the IRB Approval is under the Ethical Committee of Baqai Medical University, Karachi, Ref#BUU-EC/2018/01.
Ethical approval
The study was approved by Ethical Committee of Baqai Medical University, Karachi, Pakistan Ref # BUU-EC/2018/01.
Statement of conflict of interest
The authors have declared no conflict of interest.
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