In vitro anticoagulant effect of Crassocephalum crepidioides leaf methanol extract and fractions on human blood.

BACKGROUND: Blood coagulation is a rapid and efficient process that produces clot formation which requires regulation. A derangement of blood coagulation is a feature of many disease conditions. This study investigated the in vitro effects of Crassocephalum crepidioides Benth S. Moore leaf methanol (crude) extract and its partitioned solvent fractions on blood coagulation of Healthy human volunteers.
METHODS: The secondary metabolites from dried and ground C. crepidioides leaves were extracted with 70% methanol, and the concentrated crude extract was subsequently subjected to solvent partitioning with Hexane, Ethyl acetate, and Butanol. Varying concentrations (5-20 mg/mL) of the extract and fractions were tested in vitro on blood coagulation profile; clotting time (CT), prothrombin time (PT), and activated partial thromboplastin time (aPTT) of apparently healthy human volunteers, while phytochemical characterization of the Hexane fraction was done by gas chromatography-mass spectrometry (GC-MS).
RESULTS: C. crepidioides leaf methanol extract and fractions significantly (P<0.05) prolonged the clotting time, prothrombin and activated partial thromboplastin times in the blood obtained from the volunteers. The highest prolongation effect was recorded with the Hexane fraction at concentration of 10mg/mL. GC-MS analysis of the Hexane fraction indicated the presence of phytochemicals such as unsaturated fatty acids and esters, phenolic compounds, flavonoids, and coumarin-related compounds known to exhibit antiaggregant, antiplatelet and antimicrobial activities.
CONCLUSION: These results showed that C. crepidioides possesses bioactive components with anticoagulant properties which may be exploited in the treatment of blood coagulation disorders.

Introduction

Hemostasis is an actively changing process in which coagulation of blood starts and ends in a swift and highly controlled manner. This process involves three fundamental components; the vascular wall, the platelets, and the coagulation cascade (waterfall reactions). These components are essential for normal hemostasis to achieve two major purposes: to maintain blood in a liquid, clot-free state, and to induce a swift and localized blood clot at the site of vesicular injury.1 The reactions of hemostasis include spontaneous vasoconstriction, aggregation of platelets, blood clotting, and fibrinolysis (clot dissolution).

Blood clotting is an intricate cascade of reactions that involves many proteins (factors) which must act in an exact sequence to produce clot formation. The process is rapid and efficient and requires regulation because, if not controlled, excessive clotting can lead to thrombosis. A shift in the balance between blood coagulation and inhibition of coagulation to favor either pro- or anticoagulation may result in life-threatening thromboembolism or hemorrhage.2 Control of this process under many clinical situations requires drug interventions that aim at preventing tissue damage caused by reduced blood flow that occurs when coagulation process blocks the blood supply to a tissue area or an organ.3

Anticoagulants are chemical agents (compounds) that interact with the body’s natural blood coagulation system to treat and prevent abnormal blood clots like Deep vein thrombosis (DVT) and Pulmonary embolism (PE) which are types of Venous thromboembolism (VTE), and Atrial fibrillation.4 Anticoagulant drugs are widely used to control blood coagulation in both healthy and diseased conditions such as cardiovascular disease, diabetes mellitus, and cancer. Although a number of these drugs have been developed over the decades, most are usually accompanied by undesirable side effects such as bleeding which can be mild or severe to the extent of bleeding in and around the brain, while the activity of some (eg warfarin) are affected by food and drug interaction.4,5 Therefore, there is increased research interest in the discovery of natural anticoagulant drugs with less toxicity and fewer side effects.

Medicinal plants have been found to be relevant sources of novel therapeutic agents. Crassocephalum crepidioides Benth S. Moore, commonly called fireweed or Redflower ragleaf, is an annual edible plant that is widespread in tropical and sub-tropical regions.6,7 It is eaten by humans in many countries of Africa. The succulent leaves and stems are used as vegetable in soup and stews especially in the West and Central Africa, and it is locally used in the treatment of wounds, boils, burns, indigestion, and stomach ulcer.8–12 C. crepidioides preparations have been cited in the scientific literature as having anti-inflammatory, antioxidant, antibiotic, anti-helminthic, cytoprotective, hepatoprotective, and antidiabetic activities.12–18

C. crepidioides was demonstrated to have protective activity against oxidative damage of hepatic cells, exert cancer chemopreventive and antitumor actions.19,20 Investigations have also shown the plant to be a useful protein source in both human and animal diet which quality can be enhanced through supplementation, and a good source of nutraceuticals in prevention and treatment of diseases.8,21

In spite of the ethnomedicinal reports of C. crepidioides being used in the treatment of wounds, boils and skin-related conditions in Africa and some other parts of the world, there are limited, or no scientific investigation published on its effects on blood coagulation. Therefore, it is essential to investigate this claim and explore the potentials of C. crepidioides as a medicinal plant in the treatment of blood coagulation defects.

Materials and methods

Drugs and chemicals

All the reagents used were of analytical grade.

Reagent kits for Prothrombin Time (PT) and Activated partial thromboplastin time (aPTT) were purchased from Diagen Diagnostic Reagents Ltd., Thame, Oxon, UK.

Plant materials

Crasssocephalum crepidioides was locally obtained from farms in Ilisan-remo, Ogun State, South-Western Nigeria. The plant sample was identified at the IFE herbarium, Obafemi Awolowo University, Ile-Ife, Osun State, Nigeria. A voucher specimen was deposited with the voucher specimen registration No: IFE 17,634.

Preparation of plant sample

C. crepidioides leaves were oven-dried at 40 °C and ground into powder using an electric blender and stored in the refrigerator. The ground sample was soaked with 70% methanol using a ratio 1:8 (w/v) for 48hr at room temperature accompanied by intermittent shaking. The suspension was then filtered through a fine muslin cloth followed by Whatman No 1 filter paper.22 The crude extract was evaporated under reduced pressure using a rotary evaporator, then dried to completion in hot air- oven at 40 °C and stored in the refrigerator at 4 °C until further use. The dried extract was reconstituted with water and subjected to solvent partitioning using Hexane, Ethyl acetate and Butanol sequentially.23

Blood sample collection and preparation of plasma

Blood samples were collected from 15 healthy adult volunteers of both sexes (ages 18–35 years old), with no medication history for at least one week before blood sample collection. The volunteers were duly informed about the research, and their willingness to participate in the research was documented by the signing of written informed consent.

Blood (10ml) was drawn by venipuncture from ante-cubital part of the arm; 5ml of the whole blood was directly used for the clotting time measurement, while the remaining 5ml was transferred into centrifuge tubes containing 3.2% trisodium citrate solution (1 part of trisodium citrate solution: 9 parts of blood). This was immediately centrifuged at 2500g for 10mins to obtain pure platelet plasma (PPP). The plasma was separated and stored in the refrigerator at −4 °C until use.

Blood clotting time measurement

In vitro Clotting time measurement was carried out using a modified method of Lee and White as reported by Osoniyi and Onajobi.24 Clotting tubes containing 0.5ml each of crude extract and fractions of C. crepidioides suspended in Phosphate Buffered Saline (PBS) at varying concentrations of 5–20 mg/mL, PBS (control), and Acid citrate dextrose (anticoagulant) were incubated in a water bath at 37 °C. Freshly drawn blood (0.5ml) was carefully transferred by running it down the side of the tube into the contents of each of the incubated tubes, while simultaneously starting a stopwatch. At 30s interval, the tubes were gently slanted to an angle of 45° to check for blood clot formation. The time for the first observation of clot was recorded, and the slanting at interval continued until the tubes could be inverted without blood flowing. The stopwatch was stopped instantly, and the time was recorded as the final clotting time.

Prothrombin time (PT)

Prothrombin Time was determined according to the method of Brown, as reported by Osoniyi and Onajobi.24,25 Diagen Calcium Thromboplastin Reagent kit was used. Calcium Thromboplastin reagent was reconstituted with distilled water based on manufacturer’s instruction and pre-warmed in a water bath at 37 °C for about 10 mins. Plasma (0.1 mL) was pipetted into clotting tubes and incubated in a water bath for 2–3mins at 37°C. Then, 0.1 mL of PBS (for control), and 5, 10, and 20 mg/mL of plant fractions for the test were added. Calcium thromboplastin reagent (0.1 mL) was swiftly added to the mixture, while simultaneously starting a stopwatch. The tubes were gently tilted (angle of 45°) at regular intervals until a clot was formed. The stopwatch was instantly stopped, and the time was recorded.

Activated partial thromboplastin time (aPTT)

aPTT was determined according to the method used by Brown, as reported by Osoniyi and Onajobi using a Diagen Kaolin reagent kit.24,25 The partial thromboplastin reagent (Kaolin Platelet substitute mixture), which is a mixture of Kaolin and Phospholipid was reconstituted according to the manufacturer’s instruction. The resulting suspension and 0.02 M calcium chloride were separately pre-warmed at 37 °C in a water bath. Plasma (0.1 mL) was pipetted into clotting tubes and incubated in a water bath for 2–3 mins at 37 °C, after which 0.1 mL partial thromboplastin reagent was added to the tubes and the contents rapidly mixed. The mixture was further incubated for 3 mins, after which 0.1 mL of PBS (for control), and extract solution (5, 10, and 20 mg/mL) of plant fractions for the test were added, followed by 0.1ml pre-warmed calcium chloride, while simultaneously starting a stopwatch. The tubes were gently tilted at regular intervals until a clot is formed. The stopwatch was instantly stopped, and the time for clot formation was recorded.

Phytochemical characterization

The phytochemical characterization of the Hexane fraction was done using Gas Chromatography-Mass Spectroscopy (GC-MS).

Statistical analysis

The results were expressed as the Arithmetic mean plus or minus Standard error of the mean (SEM). Data were statistically analyzed by both one- and two-way Analysis of Variance (ANOVA) followed by Tukey’s Multiple comparisons (one-way ANOVA) and Sidak’s posthoc (two-way ANOVA) using GraphPad Prism 7.0. P-values less than 0.05 (P<0.05) were considered statistically significant.

Results

C. crepidioides leaf methanol extract and fractions prolonged the Clotting time in healthy human blood

Recorded clotting times with C. crepidioides leaf methanol extract showed that clotting time was increased with increased concentration, reaching a peak at 12.5 mg/mL after which there was a decline with further increase in concentration (Figure 1). No clot formation was observed in blood treated with Acid Citrate Dextrose solution, even after 24 hrs. This result suggests the presence of anticoagulant(s) in C. crepidioides which functions optimally within a narrow concentrations range.

Figure 1

In vitro clotting time of blood from normal volunteers with varying concentrations of C. crepidioides methanol extract. The extract was suspended in phosphate-buffered saline. Results are Mean ± SE values (n=15) for each concentration.

All partitioned fractions of C. crepidioides caused significant prolongation of clotting time at tested concentrations compared with the Control (whole blood with PBS) and Normal (whole blood alone). Highest clotting times were observed with the Hexane and Aqueous fractions (Figure 2). Clotting time was significantly (P<0.05) longer at concentration of 10 mg/mL compared to 20 mg/mL with the Methanol (crude) extract as well as Hexane and Ethyl acetate fractions (Figure 3).

Figure 2

Mean clotting time of normal human blood treated with the leaf extract and fractions at 10 mg/mL. Data are mean ± SEM (n=15). All fractions and extract were suspended in PBS.

Abbreviations: EA, Ethyl acetate; WBA, whole blood alone, Control, test control consisting of whole blood and PBS (vehicle).

Figure 3

In vitro clotting time of normal human blood treated with the fractions at 5 mg/mL, 10 mg/mL & 20 mg/mL. Results are Mean ± SE values (n=15). All fractions were suspended in PBS.

Abbreviations: WBA, whole blood alone; Control, test control consisting of whole blood and PBS (vehicle).

C. crepidioides leaf methanol extract and fractions prolonged the Prothrombin time (PT) in normal human plasma

The methanol extract and all fractions of C. crepidioides at 10mg/mL significantly (P<0.0001) prolonged the PT compared with the control (Figure 4). There was no significant difference in Prothrombin times recorded with the Hexane fraction at concentration of 10 mg/mL compared with 20 mg/mL, while significantly (P<0.05) shorter PTs were recorded at 20 mg/mL compared with 10 mg/mL with other fractions.

Figure 4

Prothrombin time of normal human plasma treated with all fractions at 10 mg/mL. Results are Mean ± SE values (n=15).

Abbreviations: PA, Plasma alone; Control, test control consisting of Plasma and PBS (vehicle).

The fractions eliciting highest CT prolongation effect (Hexane and Aqueous fractions) which represent the nonpolar and polar fractions respectively and the methanol (crude) extract were tested on PT at concentrations of 5, 10 and 20 mg/mL. There was significant (P<0.001) prolongation of PT at all tested concentrations (5, 10, & 20 mg/mL) compared with the control. Prothrombin Time with Hexane fraction was significantly (P<0.05) longer than that of Aqueous fraction and methanol extract at all concentrations, while the recorded PT was significantly (P<0.05) longer at 10 mg/mL compared to other concentrations (Figure 5).

Figure 5

Prothrombin time of normal human plasma treated with the crude extract, Hexane fraction and Aqueous fraction at 5, 10 & 20mg/mL. Results are Mean ± SE values (n=15).

Abbreviations: PA, Plasma alone; Control, test control consisting of Plasma and PBS (vehicle).

C. crepidioides leaf methanol extract and fractions prolonged Activated partial thromboplastin time (aPTT) in normal human plasma

There was significant (P<0.001) prolongation of aPTT with the methanol extract and fractions at all tested concentrations compared with the control. The recorded times for Hexane and Ethyl acetate were not significantly different from one another while the aPTT for both fractions were significantly (P<0.05) longer than that of Methanol extract, Aqueous and Butanol fractions at concentration of 10 mg/mL (Figure 6). Longer aPTT times were recorded at concentration of 10 mg/mL compared with other concentrations for all tested fractions (Figure 7). Highest aPTT prolongation effects were recorded with the Hexane fraction at the tested concentrations with values of 91.90, 116.30, and 91.80 seconds at 5, 10, and 20 mg/mL respectively.

Figure 6

aPTT of Normal Human plasma treated with all fractions at 10 mg/mL. Results are Mean ± SE values (n=15).

Abbreviations: PA, Plasma alone; Control, test control consisting of Plasma and PBS (vehicle).

Figure 7

aPTT of Normal Human plasma treated with crude extract, Hexane and Aqueous fractions at 5, 10 and 20 mg/mL. Results are Mean ± SE values (n=15).

Abbreviations: PA, Plasma alone; Control, test control consisting of Plasma and PBS (vehicle).

GC-MS phytochemical characterization

GC-MS analysis of the hexane fraction of C. crepidioides leaves revealed several bioactive compounds which include Eugenol (S/N 2) with antiaggregant activity; Thujone (S/N 1) with Antiplatelet activity; 1,9-octadecadiene with no known activity; coumarin-related compounds, Benzofuran and Benzofuranone (coumarin-3-one; S/N 3&4); and α-Linolenic acid (9,12,15-Octadecatrienoic acid; S/N 11) which possesses antiaggregant activity (Table 1). Other compounds and phenolic compounds with some other biological activities were tentatively identified. The reported antifungal, antiseptic, and antimicrobial activities of the phenolic compounds identified may be responsible for its ethnomedical use in the treatment of wounds.

Table 1

Some GC – MS identified phytochemical components of the Hexane fraction of C. crepidioides leaf extract with possible anticoagulant activity

S/N	Retention time (mins)	Name of compound (Library ID)	Molecular formula	Peak Area (%)	Reported Biological Activity
1	13.640	Thujone	C10H16O	0.56	Antiplatelet, Antibacterial, Antifungal, Antinociceptive, Insecticidal, Anthelmintic Antioxidant.26,27
2	14.180	Eugenol	C10H12O2	4.43	Antiaggregant.28 Anti-inflammatory, Antiseptic.29
3	10.286	Benzofuran	‎C8H6O	1.43	Antidepressant, Anticancer, antiviral, antifungal, antioxidant, anti-psychotic, anti-inflammatory.30
4	19.795	Benzofuranone	C8H6O	2.99	Antioxidant, Anticancer.27
5	22.151	1,9 octadecadiene	C18H34	0.78	Not stated
6	29.404	9,12,15-Octadecatrienoic acid (α-linolenic acid)	C18H30O2	4.52	Antiaggregant, Anti-Inflammatory, Hypolipidemic, Anti-leukotriene, Antiprostatic, Immunostimulant, Vasodilator, 5-alpha reductase inhibitor.27
7	5.449	Benzene acetaldehyde	C8H8O	1.11	AntioxidantAntibacterial, Anaesthetic.

Discussion

Anticoagulant and procoagulant drugs are widely used to control blood coagulation in both healthy and diseased conditions such as cardiovascular disease, diabetes mellitus, and bleeding disorders. Although a number of these drugs have been developed over the years, most are usually accompanied by undesirable side effects. Therefore, there is still an unmet need for discovery of novel anticoagulant and procoagulant drugs with fewer side effects. The present study investigated the in vitro effects of C. crepidioides leaves methanol (crude) extract and its partitioned solvent fractions on blood coagulation of Healthy human volunteers.

The results showed significant prolongation of the clotting time by the methanol extract in a concentration-dependent manner with an optimum at 12.5 mg/mL and a decline in clotting time with further increase in concentration. This suggests that clotting time prolongation effect of C. crepidioides crude leaf extract operates optimally within a narrow concentration range. Similar concentration-dependent clotting time elongation effects were observed with the partitioned solvent fractions; all the fractions significantly prolonged the clotting time beyond the control value and, in most cases, clotting time at concentrations of 5 and 20 mg per mL were lower than that observed at 10 mg per mL. A comparison of the effect of the different fractions on the clotting time showed that the hexane fraction exhibited the highest anticlotting activity. This result is comparable with the report by Ajugwo et al that Pentaclethra macrophylla seeds increased, in vitro, the clotting times of normal human blood with an optimum concentration of 100 mg/mL.31 The highest anticlotting activity observed with the hexane (non-polar) fraction compared with the polar (aqueous, butanol and methanol) fractions suggests that the major anticoagulant components of C. crepidioides leaf are non-polar. That is, hexane soluble compounds are mainly responsible for the plant anticoagulant activity.

The PT and aPTT were significantly increased at all tested concentrations of the methanol extract and fractions of the plant. Similarly, Ramya et al reported increased PT in vitro anticoagulant activity of Nelumbo nucifera leaf extracts on normal healthy blood plasma.32 Mahajan & More also reported increased PT of Human blood in Anticoagulant activity study with Aqueous and Methanol extracts of Enicostemma littorale, Acheranthus aspera, Abutilon indicum, and Tridax procumbens, while AL-Farawachi & AL-Badranii reported increased PT and aPTT in anticoagulant studies with Eminium spiculatum Aqueous leaf extract in rabbits.33,34

The PT and aPTT are coagulation parameters used in determining the mechanism of clotting. Prothrombin time (PT) is an effective assay for evaluating the activity of the factors of the extrinsic coagulation pathway, while the aPTT is used for evaluating the activity of factors of the intrinsic and common pathways. The PT is a standard test for monitoring coumarin therapy (vitamin K antagonists), while the aPTT is usually used to monitor the effectiveness of heparin treatments.35 In clinical evaluation, a long aPTT and/or PT indicates an anomaly in activities of specific clotting factors; for example, abnormally long aPTT but normal PT indicate a need to assay factors VIII, IX, and XI of the contact pathways. If both the PT and aPTT are affected, this points at factors V, X and prothrombin (factor II) of the common pathway.36 Thus, the prolonged PT and aPTT by C. crepidioides treatment suggest inhibition of factors V, X and prothrombin of the common coagulation pathway. Further research is required to elucidate the mechanism by which this is effected.

However, a possible mechanism of C. crepidioides leaf extract and fractions action may be through direct inhibition of the common pathway by decreasing thrombin (factor IIa) generation via inhibition of factor Xa and its cofactor Va, or by blocking the interaction of thrombin with substrate fibrinogen thus preventing the formation of fibrin. These suggest a possible presence of protease inhibitor in C. crepidioides leaf which may inhibit these proteases, thus preventing the conversion of the zymogens to active factors Xa, Va, and thrombin. C. crepidioides active component(s) may also activate the natural anticoagulant pathway by binding to Antithrombin III, causing a conformational change which could result in activation of protein C (PC) to activated protein C (APC), which in conjunction with its cofactor (protein S) inhibit factors Va and VIIIa (cofactors for activation of factors Xa and IIa). This ultimately prevents the activation of factor Xa and thrombin of the common pathway.

The common anticoagulant drugs used in the treatment of thrombotic conditions include heparin, warfarin, all-trans retinoic acid, and recently developed novel anticoagulants (NOACs). Heparin is a short-acting (fast) anticoagulant which action can be reversed, warfarin is long-acting and slow, with also reversible effects, all -trans retinoic acid is slow-acting, while, NOACs are fast and cannot be reversed.4,37 Heparin exerts its anticoagulant action by binding to a specific site of Antithrombin and causing a conformational change which exposes the site that binds and inactivates factor Xa and thrombin (IIa) thus, increasing the anticoagulant activity of antithrombin to about 1,000 folds.38 Warfarin is a vitamin K antagonist which inhibits the activation or synthesis of vitamin K-dependent proteins of the coagulation pathway. These proteins include factors X, IX, VII, and prothrombin. Vitamin K is a cofactor for the carboxylase enzyme which catalyzes the γ-carboxylation of Glutamic acid (Glu) residue of the polypeptide chain of this vitamin K dependent proteins. γ-carboxylation of the glutamic acid residues of these proteins is required for their calcium-binding ability, and thus their physiological activation.39,40 Studies have reported that all-trans retinoic acid exerts its anticoagulant action by downregulating Tissue factor and upregulating thrombomodulin expression, thus increasing the antithrombotic potential of microvascular endothelial cells.41–43 C. crepidioides leaf extract showed a narrow concentration range of activity peak which indicates fast and reversibility of action similar to heparin. This also corroborates the hypothesized mechanism of action of inhibiting the common coagulation pathway similar to that of heparin.

The GC-MS characterization of the hexane fraction of C. crepidioides leaf indicated the presence of several bioactive compounds with various biological activities including Benzofuranone, Benzofuran (coumarin-related compounds), Eugenol, other phenolic compounds, and flavonoids. Alpha-linolenic acid (9,12,15-Octadecatrienoic acid) has been reported to act as an antiaggregant (which decreases platelet aggregation and inhibits thrombus formation); Eugenol was reported as an anticoagulant agent in Cinnamomum cassia.29 Thujone and flavonoids have also been reported to inhibit platelet aggregation; 1,9-octadecadiene, with no reported activity, may have anticoagulant activity, while the coumarin compounds may also function as anticoagulant agents in the plant.27,44 Adjatin et al similarly reported the presence of coumarins in a qualitative phytochemical screening of C. crepidioides.8 The reported antifungal, antiseptic, and antimicrobial activities of the phenolic compounds identified in the plant may be responsible for its ethnomedical use in the treatment of wounds. Arawande et al reported that the qualitative phytochemical screening of the powdered and water extract of C. crepidioides revealed the presence of Flavonoids, Phenol, oxalate, tannin, saponin, phytate, and ascorbic acid (which also possesses antiaggregant activity).45 Bahar et al similarly reported that qualitative phytochemical profile of the methanol extract of C. crepidioides showed the presence of alkaloids, glycosides, tannins, flavonoids, phenolic compounds, saponins and reducing sugar.6,46 The findings from this study indicate that C. crepidioides leaves contain bioactive compounds which possess anticoagulant activity with great potentials in the development of novel anticoagulant drug.

Conclusion

The study showed that C. crepidioides possesses anticoagulant activity which can be exploited in the treatment of blood coagulation disorders. Further in vivo studies are required to elucidate the mechanisms by which the anticoagulant components of the plant effect their activity.