Antimalarial activity of newly synthesized chalcone derivatives in vitro

Twenty‐seven novel chalcone derivatives were synthesized using Claisen‐Schmidt condensation and their antimalarial activity against asexual blood stages of Plasmodium falciparum was determined. Antiplasmodial IC₅₀ (half‐maximal inhibitory concentration) activity of a compound against malaria parasites in vitro provides a good first screen for identifying the antimalarial potential of the compound. The most active compound was 1‐(4‐benzimidazol‐1‐yl‐phenyl)‐3‐(2, 4‐dimethoxy‐phenyl)‐propen‐1‐one with IC₅₀ of 1.1 μg/mL, while that of the natural phytochemical, licochalcone A is 1.43 μg/mL. The presence of methoxy groups at position 2 and 4 in chalcone derivatives appeared to be favorable for antimalarial activity as compared to other methoxy‐substituted chalcones. Furthermore, 3, 4, 5‐trimethoxy groups on chalcone derivative probably cause steric hindrance in binding to the active site of cysteine protease enzyme, explaining the relative lower inhibitory activity.     

The antimalarial activity of indole alkaloids and hybrids

Malaria, caused by the genus Plasmodium, remains a global public health concern. It is estimated by the World Health Organization that over 40% of the world's population lives in areas at risk for malarial transmission, and around half a million people succumb to this infectious disease annually, which is related to the rapid spread of drug-resistant parasite strains. Indole derivatives, which possess broad-spectrum pharmacological properties, play a crucial role in the discovery of new drugs. Many indole derivatives exhibited potential in vitro and in vivo activity against both drug-sensitive and drug-resistant malaria, suggesting that the indole moiety is a useful template for the development of novel antimalarial agents. This review outlines the advances in indole alkaloids and hybrids with antimalarial potential in the recent decade.     

Synthesis and evaluation of new antimalarial phenylurenyl chalcone derivatives

Phenylurenyl chalcone derivatives have been synthesized and tested as inhibitors of in vitro development of a chloroquine-resistant strain of Plasmodium falciparum, activity of the cysteine protease falcipain-2, in vitro globin hydrolysis, beta-hematin formation, and murine Plasmodium berghei malaria. The most active antimalarial compound was 1-[3'-N-(N'-phenylurenyl)phenyl]-3(3,4,5-trimethoxyphenyl)-2-propen-1-one 49, with an IC(50) of 1.76 microM for inhibition of P. falciparum development. Results suggest that chalcones exert their antimalarial activity via multiple mechanisms.     

吡唑杂合体的抗疟疾活性

疟疾是由按蚊叮咬或输入携带疟原虫血液引起的一类高传染性疾病,其临床症状包括发热、头痛、呕吐等,如不及时治疗可能危及生命。尽管临床上使用的抗疟疾药物对疟疾的防控不可或缺,但随着长期广泛使用甚至滥用,恶性疟原虫对抗疟药物产生了不同程度的耐药性。为克服耐药性,研发新型抗疟疾药物势在必行。吡唑类化合物具有包括抗疟疾在内的多种生物活性,且某些吡唑类药物已广泛用于临床,故这类化合物引起了药物化学家的持续关注。本文将归纳吡唑杂合体在抗疟疾领域的最新研究进展,并讨论此类化合物的构-效关系。     

吡唑杂合体的抗疟疾活性

疟疾是由按蚊叮咬或输入携带疟原虫血液引起的一类高传染性疾病,其临床症状包括发热、头痛、呕吐等,如不及时治疗可能危及生命。尽管临床上使用的抗疟疾药物对疟疾的防控不可或缺,但随着长期广泛使用甚至滥用,恶性疟原虫对抗疟药物产生了不同程度的耐药性。为克服耐药性,研发新型抗疟疾药物势在必行。吡唑类化合物具有包括抗疟疾在内的多种生物活性,且某些吡唑类药物已广泛用于临床,故这类化合物引起了药物化学家的持续关注。本文将归纳吡唑杂合体在抗疟疾领域的最新研究进展,并讨论此类化合物的构-效关系。     

Synthesis and in vitro and in vivo antimalarial activity of novel 4-anilinoquinoline Mannich base derivatives

Development of resistance has severely limited the choice of available antimalarial drugs, which clearly highlights the urgent need of novel chemotherapeutic agents for the treatment of malaria. The purpose of this study was to develop new potential antimalarial agents with 4-anilinoquinoline ring. A series of novel 4-anilinoquinoline Mannich base drug molecules have been synthesized. The synthesis involves the preparation of Mannich base and these bases subsequently coupled with 4,7-dichloroquinoline to get targeted drug molecules (Burckhalter et al. in J Am Chem Soc 70:1363–1373, 1948). Their structures were confirmed by IR, NMR, and mass spectral data. The synthesized molecules were evaluated for in vitro and in vivo antimalarial activity against the chloroquine sensitive 3D7 (West Africa) and RKL-2 strain of Plasmodium falciparum and rodent malaria parasite Plasmodium yoelii (strain N-67) in Swiss mice model, respectively (Charmot et al. in Prev Med 15:889, 1986). Except one molecule (containing diphenylamine), all the tested molecules showed activity while one of them (containing morpholine) showed promising in vitro and significant in vivo antimalarial activity under given test conditions.     

Plasmodium falciparum: Multidrug resistance

Malaria is the most lethal and debilitating disease caused by the protozoan parasite Plasmodium worldwide. The most severe forms of disease and the incidence rates of mortality are associated with P. falciparum infections. With the identification of disease source and symptoms, many chemical entities were developed naturally and synthetically for administration as a potential antimalarial drug. The major classes of approved antimalarial drugs that are governed as first‐line treatment in tropical and subtropical areas include quinolines, naphthoquinones, antifolates, 8‐aminoquinolines, and endoperoxides. However, the efficacy of antimalarial drugs has decreased due to ongoing multidrug resistance problem to current drugs. With increasing resistance to the current antimalarial artemisinin and its combination therapies, malaria prophylaxis has declined gradually. New‐generation antimalarial and novel drug target are required to check the incidence of malaria resistance. This review summarizes the emergence of multidrug resistance to known antimalarial and the development of new antimalarial to resolve drug resistance condition. Few essential proteins are also discussed that can be considered as novel drug target against malaria in future.     

Synthesis and antimalarial activity of sulfonamide chalcone derivatives

A series of sulfonamide chalcone derivatives were synthesized and investigated for their abilities to inhibit beta-hematin formation in vitro and their activity against cultured Plasmodium falciparum parasites. Inhibition of beta-hematin formation was minimal in the aromatic ring of the chalcone moiety as it appeared for compounds 4b, 4d-f, and greatest with compounds 4g (IC50 0.48 microM) and 4k (IC50 0.50 microM) with a substitution of 3,4,5-trimethoxyl and 3-pyridinyl, respectively. In this study, the most active compound resulted 1[4'-N(2',5'-dichlorophenyl) sulfonyl-amidephenyl]-3-(4-methylphenyl)-2-propen-1-one 4i, effective as antimalarial by the inhibition of cultured P. falciparum parasites (1 microM). These studies open up the novel possibility of development of sulfonamide derivatives as antimalarials that target beta-hematin formation and the inhibition of the development of cultured P. falciparum parasites, which should help delay the rapid onset of resistance to drugs acting at only a single site. Results with these assays suggest that chalcones exert their antimalarial activity via multiple mechanisms.     

Antimalarial quassinoids: past,present and future

This review is a compilation of the investigations reported to date on the sources, isolation, chemistry and antimalarial activities of natural quassinoids and their synthetic and semisynthetic analogs. It also provides an analysis of the in vitro structure–activity relationship of quassinoids for further evaluation in animal models. The introduction of non-nitrogenous antimalarial drugs has created a new era of malaria chemotherapy to treat Plasmodium falciparum strains that are resistant to existing nitrogenous drugs and the rising incidence of the deadly cerebral malaria. Many antimalarial quassinoids are discovered from simaroubaceous plants that are used traditionally to treat fever and malaria, thereby reiterating the critical role of ethnopharmacology as a rich source of novel drug discovery.     

Incorporation of basic side chains into cryptolepine scaffold: structure-antimalarial activity relationships and mechanistic studies

The synthesis of cryptolepine derivatives containing basic side-chains at the C-11 position and their evaluations for antiplasmodial and cytotoxicity properties are reported. Propyl, butyl, and cycloalkyl diamine side chains significantly increased activity against chloroquine-resistant Plasmodium falciparum strains while reducing cytotoxicity when compared with the parent compound. Localization studies inside parasite blood stages by fluorescence microscopy showed that these derivatives accumulate inside the nucleus, indicating that the incorporation of a basic side chain is not sufficient enough to promote selective accumulation in the acidic digestive vacuole of the parasite. Most of the compounds within this series showed the ability to bind to a double-stranded DNA duplex as well to monomeric hematin, suggesting that these are possible targets associated with the observed antimalarial activity. Overall, these novel cryptolepine analogues with substantially improved antiplasmodial activity and selectivity index provide a promising starting point for development of potent and highly selective agents against drug-resistant malaria parasites.     

The design and development of imidazothiazole–chalcone derivatives as potential anticancer drugs

Introduction: Imidazothiazole derivatives have long been therapeutically used for the treatment of various diseases. In recent years, the imidazothiazole and chalcone moieties have emerged as important pharmacophores in the development of antitumor agents. Imidazothiazole–chalcone conjugates can be accessed by covalently binding these two powerful pharamacophore units. These conjugates are known to exhibit a wide range of biological properties, including anticancer, antimicrobial, anti-inflammatory and immunosuppressive activities. Their promising biological profile and easy synthetic accessibility have triggered investigations directed at the design and development of new imidazothiazole–chalcone conjugate derivatives as potential chemotherapeutics.

Areas covered: The present review focuses on recent reports of the syntheses and anticancer properties of various imidazothiazoles, chalcones and imidazothiazole-linked chalcone conjugates. Furthermore, the authors discuss the structure–activity relationships (SAR) of imidazothiazoles and chalcones and their conjugates as new antitumor agents, as well as in vitro and in vivo evaluation, clinical use and their future therapeutic applications.

Expert opinion: A large number of imidazothiazoles, chalcones and a new series of imidazothiazole–chalcone conjugates possess potent anticancer activity that could be further developed as drug candidates. Imidazothiazole-based conjugates could also display synergistic effect, and still there is a need to use the drug combinations permitting lower dose and development of new generation of drugs. Despite encouraging observed results for their response to tumors in clinical studies, full characterization of their toxicity is further required for their clinical usage as safe drugs for the treatment of cancer.     

Synthesis of novel benzimidazole acrylonitriles for inhibition of Plasmodium falciparum growth by dual target inhibition

Antimalarial drug resistance has emerged as a threat for treating malaria, generating a need to design and develop newer, more efficient antimalarial agents. This research aimed to identify novel leads as antimalarials. Dual receptor mechanism could be a good strategy to combat developing drug resistance. A series of benzimidazole acrylonitriles containing 18 compounds were designed, synthesized and evaluated for cytotoxicity, heme binding, ferriprotoporphyrin IX biomineralisation inhibition, and falcipain‐2 enzyme assay. Furthermore, in silico docking and MD simulation studies were also performed.The tests revealed quite encouraging results. Three compounds, viz. R‐01 (0.69 μM), R‐04 (1.60 μM), and R‐08 (1.61 μM), were found to have high antimalarial activity. These compounds were found to be in bearable cytotoxicity limits and their biological assay suggested that they had inhibitory activity against falcipain‐2 and hemozoin formation. The docking revealed the binding mode of benzimidazole acrylonitrile derivatives and MD simulation studies revealed that the protein‐ligand complex was stable. The agents exhibit good hemozoin formation inhibition activity and, hence, may be utilized as leads to design a newer drug class to overcome the drug resistance of hemozoin formation inhibitors such as chloroquine.     

四氮唑杂合体在抗疟疾领域的研究进展

疟疾主要是由恶性疟原虫引起的一类可致命传染性疾病,与艾滋病、结核病一起被认为是全球最重要的三大公共卫生问题。临床上使用的抗疟疾药物如喹啉类和青蒿素类尽管对药敏型疟疾依然高度有效,但随着耐药疟疾的不断涌现和广泛传播,现有抗疟疾药物的疗效呈逐年下降之势。因此,亟需开发新型抗疟疾药物。四氮唑作为羧基的生物电子等排体可用来取代药物中的羧基以提高药物分子的脂溶性、增加药物的生物利用度和降低毒副作用,故四氮唑被认为是最具发展前景的一类化合物。本文将着重介绍近年来四氮唑杂合体在抗疟疾领域的研究进展,并讨论此类化合物的构-效关系。     

Potent antimalarial activity of newly synthesized substituted chalcone analogs in vitro

Abstract   Several new chalcone analogues were synthesized and evaluated as inhibitors of malaria parasite. Inhibitory activity was determined in vitro against a chloroquine-sensitive Plasmodium falciparum strain of parasites. The compound 3-(4-methoxyphenyl)-1-(4-pyrrol-1-yl-phenyl)prop-2-en-1-one was found to be the most active with 50% inhibition concentration (IC₅₀) of 1.61 μg/ml. This inhibitory concentration is comparable to a prototype phytochemical chalcone, licochalcone A, with an IC₅₀ of 1.43 μg/ml. The present study suggests that small, lipophilic nitrogen heterocyclic ring A together with small hydrophobic functionality at ring B can enhance antimalarial activity. These results suggest that chalcones are a class of compounds that provides an option of developing inexpensive, synthetic therapeutic antimalarial agents in the future. Graphical Abstract  Claisen-Schmidt condensation method was employed to synthesize various substituted chalcones. Among all, 3-(4-Methoxyphenyl)-1-(4-pyrrol-1-yl-phenyl)prop-2-en-1-one was found to be most effective with IC₅₀ value of 1.6 μg/ml in vitro against chloroquine sensitive strain (3D7) of Plasmodium falciparum.      

Antiplasmodial activity of steroidal chalcones: evaluation of their effect on hemozoin synthesis and the new permeation pathway of Plasmodium falciparum-infected erythrocyte membrane

Chalcone derivatives on an estradiol framework were evaluated for their ability to inhibit the growth and development of the malaria parasite Plasmodium falciparum. Out of twelve steroidal chalcones and one indanone derivative studied, three were found to have 50% growth inhibitory concentration less than 5μm and minimum inhibitory concentration for parasite development from ring to schizont stage as ≤20μm with best activity for gallic acid-based chalcone derivative 1 as 2.07 and 10μm, respectively. Two of the active derivatives 1 and 10 did not exhibit cytotoxicity against vero cells as evident by the good selectivity ratio. Study of structure-activity relationship indicated that increasing substitution in the benzoyl ring-enhanced antiplasmodial activity. Hemozoin synthesis of the parasite remained unaffected by these derivatives. These derivatives were also investigated for their effect on parasite-induced new permeation pathway in the erythrocyte membrane by sorbitol-induced hemolysis, and four derivatives 1, 2, 9, and 10 exhibited significant inhibition (>70%) at 20μm concentration. A positive correlation was also observed among the antiplasmodial activity and inhibition of new permeation pathway. These observations suggest that steroidal chalcones with selective activity for the parasite may be considered as antimalarial leads for further optimization and preclinical study.     

Design,synthesis and biological evaluation of several aromatic substituted chalcones as antimalarial agents

Malaria is a communicable disease which is caused by protozoan's mainly Plasmodium species (P. falciparum, P. ovale, P. vivax, P. malariae and P. knowlesi). The increasing resistance of Plasmodium to available malarial drugs poses a great responsibility for the researchers in the field of malaria. To overcome this problem of resistance, this study aimed to design and synthesize a new class of antimalarial agent with chalcone as the main moiety. Chalcones, a member of flavanoid family, consist of two aromatic rings of 1,3-diphenyl-2-propen-1-one linked by a three carbon α,β-unsaturated carbonyl system. Five derivatives were designed and among them one was selected. The CC2 was then synthesized by esterification of Para amino acetophenone followed by treatment with hydrazide to form 2-(4 acetylphenoxy)acetohydrazide. This was then coupled with 2-Bromo substituted Diazotized esterified anilines, which was finally linked with substituted benzaldehyde to yield CC2. These were then structurally verified by Infra Red (IR) and Nuclear Magnetic Resonance (NMR) spectroscopy. The chalcone was then tested for in vitro growth inhibition assays using SYBR GREEN-1 Based assay and IC₅₀ values were identified. The compound CC2 showed quite promising antimalarial activity by inhibiting cysteine protease enzyme. The acute toxicity studies of the compound were carried out as per OECD guideline 425 and the results showed no toxic signs and symptoms indicating CC2 as a safe and less toxic compound.     

In vivo antimalarial activity of ginseng extracts

Context: Novel antimalarial agents are in demand due to the emergence of multidrug resistant strains. Ginseng, a medicinal plant with antiparasitic activity, contains components that can be used to treat the tropical disease malaria.

Objective: Ginsenosides and polysaccharides are active components of ginseng. This study aimed to elucidate the ability of these compounds to inhibit the replication of Plasmodium yoelii in an attempt to determine whether the medicinal uses of ginseng are supported by pharmacological effects. New antimalarial compounds may be developed from ginsenosides and water-soluble ginseng polysaccharides (WGP).

Materials and methods: Ginsenosides and ginseng polysaccharides were prepared from ginseng. Antimalarial activities were examined by 4-day tests and repository tests. Macrophage phagocytosis was tested in normal and malaria-bearing mice.

Results: Ginseng polysaccharides could inhibit residual malaria infection. After a 6-day treatment, the parasitemia reductions of WGP and acidic ginseng polysaccharide (WGPA) were 55.66% and 64.73% at 200?mg/kg/day, respectively. Ginsenosides showed significant antimalarial activity on early infection. Protopanaxadiol-type ginsenosides caused 70.97% chemosuppression at 50?mg/kg/day, higher than 52.8% of total ginsenosides at the same dose.

Discussion and conclusion: Protopanaxadiol-type ginsenosides have remarkably suppressive activity during early infection, while acidic ginseng polysaccharides have significant prophylactic activity against malaria by stimulating the immune system. We propose that the activity of ginsenosides is dependent upon non-specific carbohydrate interactions and that the activity of ginseng polysaccharides is due to immunological modulation. Ginsenosides and ginseng polysaccharides might have a potential application in antimalarial treatments.     

The therapeutic potential of semi-synthetic artemisinin and synthetic endoperoxide antimalarial agents

Artemisinin derivatives such as artesunate, dihydroartemisinin and artemether are playing an increasing role in the treatment of drug-resistant malaria. They are the most potent antimalarials available, rapidly killing all asexual stages of the parasite Plasmodium falciparum. This review highlights the recent developments in the area of improved second-generation semi-synthetic artemisinin derivatives and fully synthetic antimalarial endoperoxide drugs. In pursuit of synthetic analogues of the artemisinins, one of the major challenges for chemists in this area has been the non-trivial development of techniques for the introduction of the peroxide bridge into candidate drugs. Although chemical research has enabled chemists to incorporate the endoperoxide ‘warhead’ into synthetic analogues of artemisinin, significant drawbacks with many candidates have included comparatively poor antimalarial activity, non-stereoselective syntheses and chemical approaches that are not readily amenable to scale up. However, very recent progress with synthetic 1,2,4-trioxolanes provides a new benchmark for future medicinal chemistry efforts in this area.     

New trends in anti-malarial agents

Malaria is the major parasitic infection in many tropical and subtropical regions, leading to more than one million deaths (principally young African children) out of 400 million cases each year (WHO world health report 2000). More than half of the world's population live in areas where they remain at risk of malaria infection. During last years, the situation has worsened in many ways, mainly due to malarial parasites becoming increasingly resistant to several antimalarial drugs. Furthermore, the control of malaria is becoming more complicated by the parallel spread of resistance of the mosquito vector to currently available insecticides. Discovering new drugs in this field is therefore a health priority. Several new molecules are under investigation. This review describes the classical treatments of malaria and the latest discoveries in antimalarial agents, especially artemisinin and its recent derivatives as well as the novel peroxidic compounds.     

Malaria: an update on current chemotherapy

Introduction: Chemotherapy of malaria has become a rapidly changing field. Less than two decades ago, treatment regimens were increasingly bound to fail due to emerging drug resistance against 4-aminoquinolines and sulfa compounds. By now, artemisinin-based combination therapies (ACTs) constitute the standard of care for uncomplicated falciparum malaria and are increasingly also taken into consideration for the treatment of non-falciparum malaria.

Areas covered: This narrative review provides an overview of the state-of-art antimalarial drug therapy, highlights the global portfolio of current Phase III/IV clinical trials and summarizes current developments.

Expert opinion: Malaria chemotherapy remains a dynamic field, with novel drugs and drug combinations continuing to emerge in order to outpace the development of large-scale drug resistance against the currently most important drug class, the artemisinin derivatives. More randomized controlled studies are urgently needed especially for the treatment of malaria in first trimester pregnant women. ACTs should be used for the treatment of imported malaria more consequently. Gaining sufficient efficacy and safety information on ACT use for non-falciparum species including Plasmodium ovale and malariae should be a research priority. Continuous investment into malaria drug development is a vital factor to combat artemisinin resistance and successfully improve malaria control toward the ultimate goal of elimination.