Phenolic contents, antioxidant and anticholinesterase potentials of crude extract, subsequent fractions and crude saponins from Polygonum hydropiper L

Medicinal plants are nature’s gift and are necessary for disease-free & healthy life of human beings. Since ancient times, plants have been employed for prevention and treatment of a variety of ailments. There has been a great revival in the use of herbal remedies particularly in last decades. According to World Health Organization (WHO), approximately eighty percent of the world population relies on medicinal plants to meet their primary health care [1]. P. hydropiper, also called Smartweed (family polygonaceae), has a long history of herbal use, equally in Eastern & Western herbal medicine. Domestically, it is used as anti-inflammatory, carminative, astringent, diuretic, CNS stimulant, diaphoretic, stomachic, styptic, in bleeding and in diarrhea [2]. The plant is enriched with rutin which strengthens fragile blood vessels and helps in the prevention of bleeding [3]. Traditionally, the whole plant decoction is used to treat an extensive range of ailments like dyspepsia, diarrhea, menorrhagia, hemorrhoids and skin itching [4]. Recently antioxidant flavonoids have been isolated from leaves of P. hydropiper [5]. Other species of polygonaceae family have been reported for their effectiveness in cerebral ischemia [6], parkinson's disease [7] and neuroprotective effects [8].

Free radicals are implicated in the progression of a variety of disorders in humans including central nervous system injury, arthritis, atherosclerosis, ischemic heart diseases, gastritis, cancer and reperfusion injury of many tissues [9, 10]. Free radicals from environmental pollutants, chemical agents, radiations, toxins, spicy and deep fried foods cause reduction of immune system antioxidants, alter gene expression along with induction of abnormal proteins. Free radicals are generated in living systems during oxidation process. To counteract oxidative stress, catalase and hydroperoxidase enzymes in human body convert hydrogen peroxide and hydroperoxides to nonradical forms and hence work as natural antioxidants. Thus, due to depletion of human immune system, natural antioxidants as free radical scavengers may be necessary [11, 12]. Presently available synthetic antioxidants including butylated hydroxy toluene (BHT), butylated hydroxy anisole (BHA), gallic acid esters and tertiary butylated hydroquinon have been alleged to be associated with negative health consequences. Hence, their use is restricted and there is a tendency to substitute them with natural antioxidants [13]. Numerous reports on the antioxidant and radical-scavenging activities of crude extracts and pure natural compounds have been published [10, 14]. Among the antioxidant compounds, significant attention has been given to phenolic compounds and flavonoids. Phenolic compounds, due to the existence of the conjugated ring structures and hydroxyl groups, have the potential to function as antioxidants by scavenging the free radicals that are involved in oxidative processes via hydrogenation or complexation with oxidizing species [15].

Acetylcholinesterase (AChE) and butyrylesterase (BChE) are useful targets for the development of novel and mechanism based inhibitors, due to its role in the breakdown of acetylcholine (ACh) neurotransmitter. Inhibitors of AChE and BChE enzymes are the most valuable approaches to treat neurological diseases including Alzheimer's disease (AD) [16] and possible beneficial applications in the treatment of Parkinson's disease, ataxia and dementia [17]. AD is a persistent neurological disorder frequently associated with memory impairment, behavioral turbulence, cognitive dysfunction and imperfection in routine life activities [18, 19]. This disease results from malfunctioning of different biochemical pathways resulting in a significant decline in ACh amount [20]. ACh is involved in signal transmission in the synapse and its pharmacological action is terminated primarily by AChE and secondly by BChE [21]. Therefore inhibitors of these metabolizing enzymes have become the important alternatives in treatment of AD and other neurological diseases. Conversely, presently available drugs are associated with serious side effects including hepatotoxicity [22] and are only effective in mild type of AD [23]. Consequently, it is necessary to embark new, safe and effective drug candidates. Plants are potential sources of novel active compounds and have a long history of therapeutic use since the beginning of human era. Galanthamine, an anticholinestrase alkaloid isolated from snowdrop, has been recently approved for the treatment of AD [24]. Research has been focused on the biological effects of plants which have been traditionally used as cholinesterase inhibitors in-vitro as well as in-vivo [24, 25]. This study is focused on preliminary anticholinestrase and antioxidant potential of P. hydropiper.

Discovery and development of new antioxidant drugs is among the most exciting areas of pharmacological research. Oxygen is a vital element of aerobic life, but under certain conditions it can seriously influence our health by formation of reactive oxygen species (free radicals) leading to some potentially dangerous diseases, like coronary heart disease, diabetes, atherosclerosis, neurodegenerative disorders (AD & Dementia), cancer, immune-suppression, ageing and ulcer [33, 34]. Most common free radicals include hydroxyl, nitric oxide, superoxide & lipid peroxyl, whereas non-free radicals primarily include singlet oxygen and hydrogen peroxide [35]. Nevertheless, approximately all living organisms are protected from free radicals attack by defense system, such as a protective antioxidant system that diminish the rate of free radical formation along with another system which create chain-breaking antioxidants to scavenge & stabilize free radicals. However, when the rate of free radical generation exceeds the capacity of defense mechanisms, extensive tissue injury results [36]. Consequently, drugs with free radical scavenging abilities are useful for the prevention and therapy of these diseases [37]. Antioxidant compounds are known to show their biochemical effects via several mechanisms, including hindrance of chain initiation, chelation of metal ions, breakdown of peroxides, sustained hydrogen abstraction, reductive ability and radical scavenging. Hence, numerous methods are proposed to assess the antioxidant activity. DPPH is an extensively used model system to evaluate the free radical scavenging potential of drugs [38]. DPPH radicals are scavenged by antioxidants through the donation of hydrogen, thus forming reduced DPPH-H, which change the color from purple to yellow following reduction and is quantified by analyzing absorbance at wavelength 517 nm [39]. The ABTS assay is based on the antioxidant capacity of the samples to prevent the oxidation of ABTS to ABTS⁺⁺ radical cation.

Phenolics are a class of antioxidant compounds which function as free radical terminators [15]. Previous reports indicate that the free radicals scavenging efficiency of phenolics is dependent on their molecular weight, presence of aromatic rings and nature of OH group’s substitution [40]. Figure 1 shows extraction yield of phenolics (mg GAE/g of sample) indicating that Ph.EtAc, Ph.Chf and, Ph.Bt expressed high concentrations of phenolics. Results of DPPH and ABTS scavenging activities well correlates with phenolic content and might be attributed to presence of high molecular phenolics in addition to flavonoids in these fractions of plant. Median inhibitory values (IC₅₀) were 3, 10, 15 and 35 μg/ml for Ph.Bt, Ph.Chf, Ph.EtAc and Ph.Sp fractions in DPPH free radical scavenging assay. Likewise the IC₅₀ values for all fractions in ABTS assay were < 0.01 which are comparable to positive control galantamine (IC₅₀ < 0.01) Figure 3 and Table 1. Our findings indicate that P. hydropiper is enriched with antioxidant compounds and show its possible effectiveness in the management of free radicals induced disorders especially neurodegenerative diseases.

Medicinal plants having therapeutic potential for the treatment of neurodegenerative diseases like AD, Epilepsy and Parkinsonism have been extensively explored, still there is a continuous search for new drugs like galanthamine [24, 41]. There are several reports which specify the biological potential of plants as AChE inhibitors in-vitro as well as memory enhancers in-vivo [41, 42]. Table 2 shows AChE inhibitory activity (%) and IC₅₀ values of the plant extracts. All fractions showed concentration dependent AChE inhibitory activity. Results of the current study revealed that Ph.Hex was most effective against AChE causing 87.49% enzyme inhibition with IC₅₀ 35 μg/ml. Other fractions were also effective at 1 mg/ml concentration. The concentrations of the crude plant extracts that inhibited BChE activity by 50% (IC₅₀) are presented in the Table. Our results indicate that P. hydropiper extracts are equally effective against BChE. The strongest BChE inhibitory activities were exhibited by Ph.Aq and Ph.Hex fractions, causing 87.62 and 90.30% inhibition with IC₅₀ values of 3 and 40 μg/ml respectively.

In the light of our findings, it can be concluded that most fractions of our plant screened herein exhibited high antioxidant potential and can be related to presence of high molecular weight phenolics. The plant has also showed inhibitory activity against AChE & BChE enzymes in dose-dependent way. This warrant further investigations to exploit the potential use of the bioactive compounds in the treatment of neurodegenerative diseases. Further research linked to the isolation of the bioactive compounds via bioassay-guided isolation is in progress in our laboratory.