Controlled release of artemisone for the treatment of experimental cerebral malaria

Golenser, Jacob; Buchholz, Viola; Bagheri, Amir Reza; Nasereddin, Abedelmajeed; Dzikowski, Ron; Guo, Jintao; Hunt, Nicholas H.; Eyal, Sara; Vakruk, Natalia; Greiner, Andreas

doi:10.1186/s13071-017-2018-7

Cited by 11 publications

(6 citation statements)

References 37 publications

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“…A similar approach was applied successfully in treating mice infected with Schistosoma mansoni (Gold et al, 2017). The artemisone used in this study is a relatively new artemisinin derivative purported to be superior to the commercial artemisinins used currently (reviewed in Golenser et al, 2017). Like other artemisinins, artemisone demonstrates anti-inflammatory properties (Guiguemde et al, 2014;Lu et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Treatment of Experimental Cerebral Malaria by Slow Release of Artemisone From Injectable Pasty Formulation

et al. 2020

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Malaria caused by Plasmodium falciparum causes numerous cases of morbidity with about 400,000 deaths yearly owing, mainly, to inflammation leading to cerebral malaria (CM). CM conventionally is treated by repetitive administration of anti-plasmodial drugs and supportive non-specific drugs, for about a week. A mouse model of CM caused by Plasmodium berghei ANKA, in which brain and systemic clinical pathologies occur followed by sudden death within about a week, was used to study the effect of artemisone, a relatively new artemisinin, within an injectable pasty polymer formulated for its controlled release. The parasites were exposed to the drug over several days at a non-toxic concentrations for the mice but high enough to affect the parasites. Artemisone was also tested in cultures of bacteria, cancer cells and P. falciparum to evaluate the specificity and suitability of these cells for examining the release of artemisone from its carrier. Cultures of P. falciparum were the most suitable. Artemisone released from subcutaneous injected poly(sebacic acid-ricinoleic acid) (PSARA) pasty polymer, reduced parasitemias in infected mice, prolonged survival and prevented death in most of the infected mice. Successful prophylactic treatment before infection proved that there was a slow release of the drug for about a week, which contrasts with the three hour half-life that occurs after injection of just the drug. Treatment with artemisone within the polymer, even at a late stage of the disease, helped to prevent or, at least, delay accompanying severe symptoms. In some cases, treatment prevented death of CM and the mice died later of anemia. Postponing the severe clinical symptoms is also beneficial in cases of human malaria, giving more time for an appropriate diagnosis and treatment before severe symptoms appear. The method presented here may also be useful for combination therapy of anti-plasmodial and immunomodulatory drugs.

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Section: Introductionmentioning

confidence: 99%

Treatment of Experimental Cerebral Malaria by Slow Release of Artemisone From Injectable Pasty Formulation

et al. 2020

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“…A PCL-MPEG (methoxypoly(ethylene glycol)) nanoparticle was designed and loaded with artemisone to treat cerebral malaria. The in vivo results demonstrated improved pharmacokinetic behavior, antiplasmodial activity, and anti-inflammatory effects in P. berghei ANKA infected C57BL/6 mice …”

Section: Polymeric Nanocarrier Based Antimalarial Drug Delivery Systemsmentioning

confidence: 87%

Polymeric Nanoparticle Based Diagnosis and Nanomedicine for Treatment and Development of Vaccines for Cerebral Malaria: A Review on Recent Advancement

Patra

Singh

Wasnik

et al. 2021

ACS Appl. Bio Mater.

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Cerebral malaria occurs due to Plasmodium falciparum infection, which causes 228 million infections and 450,000 deaths worldwide every year. African people are mostly affected with nearly 91% cases, of which 86% are pregnant women and infants. India and Brazil are the other two countries severely suffering from malaria endemicity. Commonly used drugs have severe side effects, and unfortunately no suitable vaccine is available in the market today. In this line, this review is focused on polymeric nanomaterials and nanocapsules that can be used for the development of effective diagnostic strategies, nanomedicines, and vaccines in the management of cerebral malaria. Further, this review will help scientists and medical professionals by updating the status on the development stages of polymeric nanoparticle based diagnostics, nanomedicines, and vaccines and strategies to eradicate cerebral malaria. In addition to this, the predominant focus of this review is antimalarial agents based on polymer nanomedicines that are currently in the preclinical and clinical trial stages, and potential developments are suggested as well. This review further will have an important social and commercial impact worldwide for the development of polymeric nanomedicines and strategies for the treatment of cerebral malaria.

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“…Most importantly, it is not converted to dihydroxyartemisinin, to which some parasite resistance was found. [ 4–6 ] Additionally, ART is regarded as a crystalline drug with a hydrophobic structure. [ 5,6 ] The main concern related to ART is its low bioavailability and its poor solubility in aqueous solutions.…”

Section: Introductionmentioning

confidence: 99%

Meeting the Needs of a Potent Carrier for Malaria Treatment: Encapsulation of Artemisone in Poly(lactide‐co‐glycolide) Micro‐ and Nanoparticles

Heidari

Golenser

Greiner

2022

Part & Part Syst Charact

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the death of about 435 000 people especially in tropical and subtropical regions. [3] Among artemisinin derivatives, artemisone (ART) is considered a most potent agent for treatment of malaria, owing to its lack of neurotoxicity, anti-plasmodial, anti-inflammatory, and significant therapeutic effect against cerebral malaria. Most importantly, it is not converted to dihydroxyartemisinin, to which some parasite resistance was found. [4][5][6] Additionally, ART is regarded as a crystalline drug with a hydrophobic structure. [5,6] The main concern related to ART is its low bioavailability and its poor solubility in aqueous solutions. [7] To overcome these drawbacks, studies have been carried out to incorporate the drug into various types of nanoand microcarriers. [8][9][10] Different types of carriers such as liposomes and polymeric particles have been evaluated for the controlled delivery of drugs. [11][12][13] Specifically, great attention is drawn toward the polymeric nano-and microparticles as drug delivery systems due to their controlled and sustained drug delivery behavior. [14][15][16] In comparison with free drugs, polymeric particles exhibit some advantages ranging from improved drug bioavailability to the ability of releasing the drug in a controlled manner and being compatible with varying administration routes. Compared with liposomes, polymeric particles have the advantage of increased storage capacity, lower cytotoxicity, [15,18] improved in vivo stability [19] against enzymatic degradation [11] and increased drug solubility in aqueous medium, [20] reducing drug side effects. [21] These lead to extended drug circulation time, lower dosing frequency and consequently and most important increased patient compliance. [22,23] Poly(lactide-co-glycolide) (PLGA), an aliphatic polyester which is known as a biocompatible and biodegradable polymer has been widely used for nanoparticle fabrication and drug delivery systems. [24][25][26] It hydrolyzes within the body, to produce glycolic acid, which is a nontoxic biodegradable monomer. [27] Characteristics such as particle size, zeta potential, and drug loading could be tuned accurately by changing the type and quantity of polymer, amount of drug, solvent, and surfactant. [17] The resulting size of the particle is of great importance, as it plays a significant role in the stability of the particle dispersion, drug release, and cellular uptake. For an efficient drug delivery, Biodegradable polymer nano-and microparticles are of interest as drug carriers due to their capability to modulate drug release. Two different methods, including solvent displacement and spray drying, are used, resulting in the fabrication of Artemisone (ART)-loaded polymeric nano-and microparticles, respectively. Scanning electron microscopy, transmission electron microscopy, dynamic light scattering, and asymmetric flow field flow fractionation (AF4) are employed to evaluate the morphology and size of the particles. The encapsulation and loading efficiency of the drug as well as cumulative rel...

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Controlled release of artemisone for the treatment of experimental cerebral malaria

Cited by 11 publications

References 37 publications

Treatment of Experimental Cerebral Malaria by Slow Release of Artemisone From Injectable Pasty Formulation

Treatment of Experimental Cerebral Malaria by Slow Release of Artemisone From Injectable Pasty Formulation

Polymeric Nanoparticle Based Diagnosis and Nanomedicine for Treatment and Development of Vaccines for Cerebral Malaria: A Review on Recent Advancement

Meeting the Needs of a Potent Carrier for Malaria Treatment: Encapsulation of Artemisone in Poly(lactide‐co‐glycolide) Micro‐ and Nanoparticles

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