Parasites, Hosts and Diseases

Parasit Host Dis

2982-5164 2982-6799

The Korean Society for Parasitology and Tropical Medicine

10.3347/PHD.23044

phd-23044

Original Article

Evaluating the activity of N-89 as an oral antimalarial drug

https://orcid.org/0000-0001-5550-479X

Aly

Nagwa S. M.

12 Matsumori

Hiroaki

1 Dinh

Thi Quyen

1 Sato

Akira

13 Miyoshi

Shin-ichi

4 Chang

Kyung-Soo

5 Yu

Hak Sun

6 Kubota

Takaaki

7 Kurosaki

Yuji

8 Cao

Duc Tuan

9 Rashed

Gehan A.

https://orcid.org/0000-0001-6142-5983

Kim

Hye-Sook

1Department of International Infectious Diseases Control, Graduate School of Medicine, Dentistry and Pharmaceutical Sciences, Okayama University, Okayama 700-8530, Japan 2Department of Parasitology, Benha Faculty of Medicine, Benha University, Benha 13511, Egypt 3Department of Biochemistry and Molecular Biology, Faculty of Pharmaceutical Sciences, Tokyo University of Science, Chiba 278-8530, Japan 4Department of Sanitary Microbiology, Graduate School of Medicine, Dentistry and Pharmaceutical Sciences, Okayama University, Okayama 700-8530, Japan 5Department of Clinical Laboratory Science, College of Health Sciences, Catholic University of Pusan, Busan 46252, Republic of Korea 6Department of Parasitology and Tropical Medicine, School of Medicine, Pusan National University, Yangsan 626-870, Republic of Korea 7Department of Natural Products Chemistry, Graduate School of Medicine, Dentistry, and Pharmaceutical Sciences, Okayama University, Okayama 700-8530, Japan 8Department of Pharmaceutical Formulation Design, Graduate School of Medicine, Dentistry and Pharmaceutical Sciences, Okayama University, Okayama 700-8530, Japan 9Department of Pharmaceutical Chemistry and Quality Control, Faculty of Pharmacy, Hai Phong University of Medicine and Pharmacy, Hai Phong, Vietnam

*Correspondence: (hskim@cc.okayama-u.ac.jp)

8 2023

21 08 2023

61 3 282 291 8 04 2023 20 07 2023

2023

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (https://creativecommons.org/licenses/by-nc/4.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Despite the recent progress in public health measures, malaria remains a troublesome disease that needs to be eradicated. It is essential to develop new antimalarial medications that are reliable and secure. This report evaluated the pharmacokinetics and antimalarial activity of 1,2,6,7-tetraoxaspiro[7.11]nonadecane (N-89) using the rodent malaria parasite Plasmodium berghei in vivo. After a single oral dose (75 mg/kg) of N-89, its pharmacokinetic parameters were measured, and t_1/2 was 0.97 h, T_max was 0.75 h, and bioavailability was 7.01%. A plasma concentration of 8.1 ng/ml of N-89 was maintained for 8 h but could not be detected at 10 h. The dose inhibiting 50% of parasite growth (ED₅₀) and ED₉₀ values of oral N-89 obtained following a 4-day suppressive test were 20 and 40 mg/kg, respectively. Based on the plasma concentration of N-89, we evaluated the antimalarial activity and cure effects of oral N-89 at a dose of 75 mg/kg 3 times daily for 3 consecutive days in mice harboring more than 0.5% parasitemia. In all the N-89- treated groups, the parasites were eliminated on day 5 post-treatment, and all mice recovered without a parasite recurrence for 30 days. Additionally, administering oral N-89 at a low dose of 50 mg/kg was sufficient to cure mice from day 6 without parasite recurrence. This work was the first to investigate the pharmacokinetic characteristics and antimalarial activity of N-89 as an oral drug. In the future, the following steps should be focused on developing N-89 for malaria treatments; its administration schedule and metabolic pathways should be investigated.

New antimalarial candidate oral N-89 pharmacokinetics in vivo

Introduction

Malaria is a global health concern severely affecting the developing countries responsible for significant morbidity and mortality cases in malaria-endemic regions. It is estimated that around 619,000 people die from malaria annually [1]. Recently, several new antimalarial drugs or their combinations have been developed. Also, there are several modern generic versions of current medications, but none have enough data to support their mass usage. The World Health Organization (WHO) suggested artemisinin combination therapy (ACT) as an initial therapy for uncomplicated malaria patients. ACT combines rapidly acting artemisinin derivatives with a longer-acting (slowly eliminated) antimalarial drug. The artemisinin derivative rapidly clears parasites from circulation. The longer-acting antimalarial drug with higher elimination half-lives remove the remaining parasites and provide a period of post-treatment prevention [2]. However, ACT is associated with a nearly 50% cure failure rate in some areas in Southeast Asia [3]. ACT-resistant Plasmodium falciparum has emerged, and its area of infection is expanding [4,5]. The WHO malaria eradication program includes discovering new compounds with antiparasitic action and a high therapeutic index with minimal toxicity [6]. Therefore, to overcome ACT and other drug-resistant P. falciparum, there is an urgent need to develop new antimalarial drugs structurally distinct from the available drugs and target different metabolic pathways [7].

We discovered a new antimalarial drug from synthetic endoperoxide compounds, 1,2,6,7- tetraoxaspiro[7.11]nonadecane (N-89) [8]. N-89 exhibited strong antimalarial activity in vitro [8–11] and was used as a potential candidate to treat childhood malaria in ointments. This study explored the different formulations that can be applied to skin and area sizes to maintain an effective N-89 plasma concentration for a prolonged time [12]. Additionally, a combination therapy involving N-89 with mefloquine or pyrimethamine was effective against P. berghei-infected mice [13]. To determine the suitable antimalarial candidates using N-89 structure-based derivatives, 6-(1,2,6,7-tetraoxaspiro[7.11]nonadec-4-yl) hexan-1-ol (N-251), having similar antimalarial activity as N-89, was selected. The antimalarial activity and cure effects of N-251 without recurrence and safety test results have been previously reported [11,14]. Additionally, an analytical detection method was developed for N-251 [15,16]. During the development of N-251 as a new antimalarial drug, issues like low yields following multiple synthetic steps have been reported; therefore, different synthetic preparation methods for N-251 are being developed [17].

The exploration of antimalarial mechanisms of N-89 demonstrated that P. falciparum endoplasmic reticulum resident calcium-binding protein (PfERC) could be a possible target [9,18], with inhibition activities during the third stage of parasite development inside red blood cells [10]. Although the functions of PfERC have not been elucidated, it may play an essential role in the division, recruitment, and protein export of malaria parasites [19–21].

A pharmacokinetic study is required to determine the suitable treatment schedule for N-89, a medication that can be of practical application. This report aimed to conduct a pharmacokinetic (PK) study for N-89 and characterize the antimalarial activity and cure effects of oral N-89 based on the PK data for the first time. We also tested the efficacy of N-89 using different administration routes.

Materials and Methods

Materials

N-89 (Fig. 1, inset) was produced in our laboratory as follows. First, methoxymethylenecy-clododecane and cyclododecanone were prepared by ozonolysis of a vinyl ether in the presence of hydrogen peroxide in diethyl ether. Next, (cyclododecylidene)bishydroperoxide was produced by combining methoxymethylenecyclododecane and cyclododecanone in the presence of peroxide and ozone in acidic conditions. N-89 was produced from (cyclododecylidene)bishydroperoxide and CsOH·H₂O in DMF [8]. Olive oil was procured from Wako (Osaka, Japan), and Chremophor EL was purchased from Sigma (St. Louis, MO, USA). All other chemicals and reagents were of analytical grade.

Mice and parasites

Institute of Cancer Research (ICR) male mice (The Jackson Laboratory, Kanagawa, Japan) and P. berghei (NK65 strain) parasites were maintained in the laboratory. P. berghei (NK65 strain) infected ICR mice died from parasite infection within one week. The experiment collected blood from a donor mouse previously infected with P. berghei when the parasitemia reached 15%. The parasitized blood was intravenously (iv) injected into mice, and P. berghei-infected mice were developed. We used ICR mice and P. berghei (NK65 strain) to study the compounds’ antimalarial activity and cure effects. The mice were reared in a 12 h light/dark cycle at room temperature (23±2°C) with free access to water and food (MF, Oriental Co. Ltd., Tokyo, Japan). The Institutional Animal Care and Use Committee of Okayama University granted consent for this study (approval number: OKU-2017199), which was carried out per the university’s guidelines.

Pharmacokinetic analysis of oral N-89

To evaluate the pharmacokinetics of N-89 in mice, a specific and sensitive liquid chromatography/tandem mass spectrometric (LC/MS/MS) method was used [15]. N-89 was administered at a single dose of 75 mg/kg orally (po) as a solution in olive oil or 30 mg/kg intravenous administration as a solution in 10% ethanol, 10% Cremophore EL, and 80% saline (1:1:8 [v:v:v]). The blood samples were collected at 0.25, 0.5, 0.75, 1, 2, 3, 4, 5, 8, and 10 h post-treatment. As it is challenging to collect multiple blood samples from a single mouse, a blood sample was collected once from a mouse at a given time, and 5 mice were used each time. Fifty mice were used for blood sample collection. The collected blood samples were centrifuged for 10 min at 945 g at 4°C. N-89 was isolated from the plasma samples using acetonitrile as a solvent, and further steps were performed as described by Okada [16]. The plasma concentration of N-89 was detected by LC/MS/MS system (LC; Agilent 1200, Agilent Technologies, Tokyo, Japan, MS/MS; API4000, AB SCIEX, Tokyo, Japan). The TSKgel Super-octyl column (Tosoh Co., Tokyo, Japan) was used to analyze a sample of 10 μl Acetonitrile: 10 mM ammonium acetate (8:2) was used as a mobile phase and supplied at 0.2 ml/min. The ESI interface in the positive MRM mode was used for N-89 measurement. The used parameters were adjusted as described by Imada [15]. N-89 parent ions (m/z, 273) and a monitoring ion 183 were detected. Multiple standard curves were created for the 5–1,000 ng/ml concentration ranges, with a correlation coefficient above 0.994.

PK parameters of N-89 were calculated using a macro program, MOMENT (EXCEL) [22,23], running on Microsoft Excel by model-independent analysis. The highest detected plasma concentration of oral N-89 (C_max) and the time required to reach the C_max (T_max) values were obtained from the experimental data. The time required to reach half of C_max is t_1/2. The area under the plasma concentration-time curve (AUC) and mean residence time were estimated from the single time course detected with mean values. All the data were expressed as the mean value (n=5). Finally, the bioavailability (F) was calculated according to the formula. F (%)=100×AUC_po×Dose_iv/AUC_iv×Dose_po.

Antimalarial activity of N-89 using different administration routes (4-day suppressive test)

The antimalarial activity of N-89 using different treatment routes was examined using an in vivo Peters’ 4-day suppressive test as described previously [24]. In the study, each healthy mouse was infected with P. berghei (NK65 strain) parasites by iv infusion of 1×10⁵ infected erythrocytes. N-89 was administered to mice at doses of 0, 10, 20, 40, and 80 mg/day for 4 days (days 0, 1, 2, and 3), either po (as a solution in olive oil), or iv (as a solution in 10% ethanol, 10% Chremophore EL, and 80% saline (10:10:80 (v:v:v)). N-89 was administered subcutaneously (sq) at doses of 0, 1, 2, 4, and 8 mg/day for 4 days (as the same solution of iv treatment). N-89 administration on day zero was performed after 2 h from parasite inoculation. The control group received the vehicles only. Five mice were used in each group. The parasitemia was determined on day 4 by performing thin blood films.

Antimalarial activity following repeated oral dosing (Cure effect)

The mice were tested by iv infusion of 1×10⁶ infected erythrocytes (day 0). Mice with more than 0.5% parasitemia were administered N-89 orally at 50 or 75 mg/kg thrice daily for three days (days 2, 3, and 4) based on the PK data. The changes in parasitemia and survival of mice were observed for 30 days.

Statistical analysis

The results were tabulated and analyzed using Microsoft Excel 2016. Percent parasitemia was calculated by dividing the number of infected erythrocytes by the total number of erythrocytes indexed and multiplied by 100. The results were expressed as the percent reduction of parasitemia compared to untreated control. ED₅₀ and ED₉₀ values (effective dose leading to the death of 50% and 90% parasites) were obtained by sigmoidal dose-response curve analysis. The data were expressed as the mean±standard deviation (SD).

Results

Pharmacokinetic analysis of N-89

The N-89 plasma concentration after a single po and iv administration is shown in Table 1 and Fig. 1. For iv administration, the plasma concentration of N-89 declined time-dependently (Fig. 1). The concentration of N-89 was 18.32 μg/ml at 0.25 h and could not be detected at 5 h, demonstrating its very short residence time in the blood and rapid metabolism or circulation in the body. The t_1/2 was 1.5 h and AUC_0→last and AUC_0→_∞ were 13.57 and 13.59 μg·h/ml, respectively. After oral N-89 treatment, the C_max was 1.59 μg/ml at 0.75 h and t_1/2 was 0.97 h. A plasma concentration of 8.1 ng/ml was detected at 8 h but could not be detected at 10 h (the detection limit of the LC/MS/MS system was 5 ng/ml). The AUC_{0→ last} was 2.37 μg·h/ml, and AUC_0→∞ was 2.38 μg·h/ml. Finally, F was calculated as 7.01%, indicating a low oral bioavailability of N-89 in ICR mice. The dotted line in Fig. 1 indicated the EC₅₀ value of P. falciparum (6.8 ng/ml) [8], and a single oral N-89 dose of 75 mg/kg remained an effective concentration for inhibition of 50% of parasites for 8 h. The plasma level of oral N-89 was between 10 and 1.59 μg/ml within 8 h and did not accumulate in the mice.

Antimalarial activity of N-89 using different administration routes (4-day suppressive test)

The N-89 antimalarial activity was examined by different routes, specifically, po, iv, and sq. The ED₅₀ and ED₉₀ values are indicated in Table 2. The ED₅₀ values were 20.5, 14.5, and 2.5 mg/kg, respectively. Low doses of sq N-89 showed high antimalarial activity compared to other treatment routes. However, after stopping the sq N-89 treatment, parasitemia increased anew, and all N-89 treated mice died on day 8. All control mice died on day 7 (mean survival was 6.8 days).

Antimalarial activity following repeated oral dosing (Cure effect)

A cure effect means that the P. berghei-infected mice had no parasites for up to one month following N-89 treatment. We evaluated the cure effect and changes in parasitemia following 75 mg/kg N-89 treatment based on the plasma concentrations of the oral data (8.1 ng/ml of N-89 was detected at 8 h). We fixed the treatment schedule thrice daily for 3 consecutive days using 0.5% parasitemia as a malaria patient model (on day 2). Oral administration of N-89 caused a decrease in parasitemia to day 3, and no parasites were observed in the blood from day 5 to 30 without parasite recurrence (Fig. 2). Parasitemia reduction below the level of detection was achieved on days 4–5 (i.e., 2–3 days after oral dosing).

The upper section of Table 3 indicates a detailed parasitemia with SD values from day 1 to 6 to evaluate the antimalarial activity during or after N-89 treatment. One mouse was cured with no parasites in the bloodstream and 4 mice had low parasitemia (below 0.015%) on day 4. All mice were cured on day 5. The survival times were determined by observing mice for 30 days. N-89 treated mice survived for more than 30 days while the mean survival day of the control mice was 5.6 (Table 3). These results reflected that the PK data of oral N-89, and 75 mg/kg of N-89 was sufficient for parasite elimination. Therefore, we studied the antimalarial activity and cure effect using a lower dose of N-89 (50 mg/kg) with the same experimental conditions.

Oral administration of a low dose of the N-89 treated group showed a decrease in parasitemia on day 3, and no parasites were observed in the blood from day 6 to 30 without parasite recurrence (Fig. 3).

The lower section of Table 3 indicates a detailed parasitemia with SD values from day 1 to 6. Four mice were cured, one mouse showed 0.01% parasitemia on day 5, and all were cured on day 6. N-89 treated mice survived for more than 30 days, while the mean survival day of the control mice was 6.2 (Table 3). This data indicated that 50 mg/kg of N-89 exhibited a complete cure effect for the malaria parasite in mice.

Discussion

Oral medication is the most popular drug administration route. Current estimates indicate that oral medication represents about 90% of the global market share of all pharmaceutical preparations designed for human use [25]. The current study aimed to accelerate antimalarial drug development efforts by investigating the potential use of the N-89 drug via different application routes to target malaria infection. Pharmacokinetics in animal studies is required to develop N-89, and the appropriate administration schedule of effective N-89 can be confirmed by detecting the PK parameters in this study. Its antimalarial effect is comparable to that of artemisinin, and its toxicity against P. falciparum is 350-fold more than that against mouse mammary tumor FM3A cells in vitro [11], indicating its selective toxicity against malaria parasites.

This study was the first to report the PK data of N-89. We evaluated the antimalarial activity using a mice model for malaria patients based on the plasma concentration of oral N-89. PK analysis of N-89 indicated that the plasma concentration of N-89 was 8.1 ng/ml and was maintained for 8 h (Fig. 1). In a previous report [8], the N-89 EC₅₀ value against P. falciparum was 6.8 ng/ml; therefore, a plasma concentration of 8.1 ng/ml could inhibit parasites in mice. The plasma level of oral N-89 within 8 h did not accumulate in mice. The sigmoidal pattern of plasma concentration of oral N-89 indicated that the maximum concentration was 1.59±1.11 μg/mL at 0.75 h and then decreased to 8.1 ng/ml after 8 h as shown in Fig. 1. The results suggested that N-89 showed antimalarial activity without accumulation effects with multiple oral administrations in the body. The t_1/2 of oral N-89 was 0.97 h (Table 1) and multiple administrations would be needed to maintain an effective plasma level of N-89. Therefore, in this study, we chose a 3-daily dosing plan of oral N-89 (50 mg/kg) for a cure effect. The oral N-89 treated group (50 mg/kg, thrice daily for 3 days) caused parasite killing, and mice were cured (Fig. 3). The F of N-89 was calculated for the first time, and it was 7.01%. The F of N-89 would be difficult to further drug development study, but a single oral N-89 compound had a complete cure effect without recurrence. To develop the next stage, we improved the detection methods and re-evaluated the PK analysis with a detailed metabolic analysis of N-89. Endoperoxide structure containing artemisinin and its derivatives reported PK data and its bioavailability showed a broad range from 1.60–26.1% using rats. [26]. There are challenges in the direct comparison of F value and needs further studies to understand detailed PK parameters using an improved N-89 detection method.

Previously, we studied the effects of an ointment of N-89. The transdermal treatment with N-89 was an effective and safe alternative route for treating malaria. The cure effect of N-89 in mice was tested at 60 mg/kg twice daily for 4 days at 0.2% parasitemia. Parasites disappeared post-treatment from day 7 in N-89 treated groups without parasite recurrence or dermal irritation [12].

Klayman et al. [27] developed a gel containing artelinic acid that was applied topically (twice/day×3 days) post-infection (dose 270 mg/kg). They prevented the death of mouse-infected P. berghei. Also, they reported that the improved formulation containing artemether instead of artelinic acid in the same experimental conditions was efficient at a lower dose of 60 mg/kg [28].

The current study examined the antimalarial activity of N-89 using a 4-day suppressive test by different routes; po, iv, and sq. Specifically, sq N-89 has antimalarial activity with a low dose of N-89. Still, sq treatment needs the support of medical staff with a disposable syringe during malaria treatment, and we did not perform further studies using sq N-89. Oral treatment is a preferable route of administration in non-complicated adult malarial patients or visitors to endemic areas because of convenience and no need for hospitalization or special techniques. Thus, we evaluated the detailed antimalarial activity and cure effect of oral N-89.

In conclusion, the data presented in this study showed the pharmacokinetics of N-89 and its complete cure effect for the first time. For the clinical application of oral N-89 in treating malaria patients, a suitable administration schedule and its metabolic pathways of N-89 should be explored.

Acknowledgments

We thank Tomoko Tanaka and Kazuaki Okada (Okayama University) for performing experiments and discussing the results. This study was supported in part by a grant from the Program of the Japan Initiative for Global Research Network on Infectious Diseases (J-GRID, JP22wm0125004) from the Ministry of Education, Culture, Sports, Science, and Technology in Japan (MEXT) and the Japan Agency for Medical Research and Development (AMED).

Author contributions

Conceptualization: Aly N, Rashed GA, Kim HS

Formal analysis: Yu HS

Funding acquisition: Miyoshi SI, Kim HS

Investigation: Aly N, Matsumori H, Dinh TQ

Methodology: Matsumori H, Dinh TQ

Project administration: Kim HS

Resources: Miyoshi SI, Kim HS

Software: Yu HS, Cao DT

Supervision: Sato A, Kubota T, Kurosaki Y, Kim HS

Validation: Aly N, Sato A, Miyoshi SI, Chang KY, Yu HS, Kubota T, Kurosaki Y, Cao DT, Kim HS

Visualization: Miyoshi SI, Kubota T, Kurosaki Y

Writing – original draft: Aly N

Writing – review & editing: Chang KY, Cao DT, Rashed GA, Kim HS

The authors have no conflicts of interest.

References

World Health Organization

World Malaria Report 2022 World Health Organization

Geneva, Switzerland

2022

https://www.who.int/publications/i/item/9789240064898

World Health Organization

Guidelines for the Treatment of Malaria World Health Organization

Geneva, Switzerland

2022

https://www.who.int/publications/i/item/guidelines-for-malaria

van der Pluijm

Imwong

Chau

Hoa

Thuy-Nhien

Determinants of dihydroartemisinin-piperaquine treatment failure in Plasmodium falciparum malaria in Cambodia, Thailand, and Vietnam: a prospective clinical, pharmacological, and genetic study

Lancet Infect Dis 2019 19 9 952 961

https://doi.org/10.1016/S1473-3099(19)30391-3

Imwong

Suwannasin

Kunasol

Sutawong

Mayxay

The spread of artemisinin-resistant Plasmodium falciparum in the Greater Mekong subregion: a molecular epidemiology observational study

Lancet Infect Dis 2017 17 5 491 497

https://doi.org/10.1016/S1473-3099(17)30048-8

Dormoi

Amalvict

Gendrot

Pradines

Methylene blue-based combination therapy with amodiaquine prevents severe malaria in an experimental rodent model

Pharma-ceutics 2022 14 10 2031

https://doi.org/10.3390/pharmaceutics14102031

Khairani

Fauziah

Wiraswati

Panigoro

Setyowati

Oral administration of piperine as curative and prophylaxis reduces parasitaemia in Plasmodium berghei ANKA-infected mice

J Trop Med 2022 2022 5721449

https://doi.org/10.1155/2022/5721449

Gebremariam

Desta

Teklehaimanot

Girmay

In Vivo antimalarial activity of leaf latex of Aloe melanacantha against Plasmodium berghei infected mice

J Trop Med 2021 2021 6690725

https://doi.org/10.1155/2021/6690725

Kim

Nagai

Ono

Begum

Wataya

Synthesis and antimalarial activity of novel medium-sized 1,2,4,5-tetraoxacycloalkanes

J Med Chem 2001 44 2357 2361

https://doi.org/10.1021/jm010026g

Aly

Hiramoto

Sanai

Hiraoka

Hiramoto

Proteome analysis of new antimalarial endoperoxide against Plasmodium falciparum

Parasitol Res 2007 100 5 1119 1124

https://doi.org/10.1007/s00436-007-0460-8

Morita

Koyama

Sanai

Sato

Hiramoto

Stage specific activity of synthetic antimalarial endoperoxides, N-89 and N-251, against Plasmodium falciparum

Parasitol Int 2015 64 1 113 117

https://doi.org/10.1016/j.parint.2014.10.007

Sato

Hiramoto

Morita

Matsumoto

Komichi

Antimalarial activity of endoperoxide compound 6-(1,2,6,7- tetraoxaspiro [7.11] nonadec-4-yl) hexan-1-ol

Parasitol Int 2011 60 3 270 273

https://doi.org/10.1016/j.parint.2011.04.001

Aly

NSM

Matsumori

Dinh

Sato

Miyoshi

Formulation and evaluation of the antimalarial N-89 as a transdermal drug candidate

Parasitol Int 2023 93 102720

https://doi.org/10.1016/j.parint.2022.102720

Aly

NSM

Matsumori

Dinh

Sato

Miyoshi

Pioneer use of antimalarial transdermal combination therapy in rodent malaria model

Pathogens 2023 12 3 398

https://doi.org/10.3390/pathogens12030398

Aly

NSM

Matsumori

Dinh

Sato

Miyoshi

Antimalarial effect of synthetic endoperoxide on Plasmodium chabaudi infected mice

Parasites Hosts Dis 2023 61 1 33 41

https://doi.org/10.3347/PHD.22119

Imada

Takahashi

Kuramoto

Masuda

Ogawara

Improvement of oral bioavailability of N-251, a novel antimalarial drug, by increasing lymphatic transport with long-chain fatty acid-based self-nanoemulsifying drug delivery system

Pharm Res 2015 32 8 2595 2608

https://doi.org/10.1007/s11095-015-1646-x

Okada

Sato

Hiramoto

Isogawa

Kurosaki

Pharmacokinetic analysis of new synthetic antimalarial N-251

Trop Med Health 2019 47 40

https://doi.org/10.1186/s41182-019-0167-4

Sato

Kawai

Hiramoto

Morita

Tanigawa

Antimalarial activity of 6-(1,2,6,7-tetraoxaspiro[7.11]nonadec- 4-yl)hexan-1-ol (N-251) and its carboxylic acid de-rivatives

Parasitol Int 2011 60 4 488 492

https://doi.org/10.1016/j.parint.2011.08.017

Morita

Sanai

Hiramoto

Sato

Hiraoka

Plasmodium falciparum endoplasmic reticulum-resident calcium binding protein is a possible target of synthetic antima-larial endoperoxides, N 89 and N 251

J Proteome Res 2012 11 12 5704 5711

https://doi.org/10.1021/pr3005315

La Greeca

Hibbs

Riffkin

Foley

Tilley

Identification of an endoplasmic reticulum-resident calcium-binding protein with multiple EF-hand motifs in asexual stage of Plasmodium falciparum

Mol Biochem Parasitol 1997 89 2 283 293

https://doi.org/10.1016/s0166-6851(97)00134-5

Fierro

Asady

Brooks

Cobb

Villegas

An endoplasmic reticulum CREC family protein regulates the egress proteolytic cascade in malaria parasites

mBio 2020 11 1 e03078 03019

https://doi.org/10.1128/mBio.03078-19

Gabriela

Matthews

Boshoven

Kouskousis

Jonsdottir

A revised mechanism for how Plasmodium falciparum recruits and exports proteins into its erythrocytic host cell

PLoS Pathog 2022 18 2 e1009977

https://doi.org/10.1371/journal.Ppat.1009977

Tabata

Yamaoka

Kaibara

Suzuki

Terakawa

Moment analysis program available on Microsoft Excel

Xenobio Metabol Dispos 1999 14 286 293

https://www.pharm.kyoto-u.ac.jp/byoyaku/Kinetics/download.html#moment

Hashimoto

Taguchi

Imoto

Yamasaki

Mitsuya

Pharmacokinetic properties of orally Administered 4′-cyano-2′-deoxyguanosine, a novel nucleoside analog inhibitor of the Hepatitis B, in viral liver injury model rats

Biol Pharm Bull 2020 43 9 1426 1429

https://doi.org/10.1248/bpb.b20-00372

Peters

The chemotherapy of rodent malaria, XXII. The value of drug-resistant strains of P. berghei in screening for blood schizontocidal activity

Ann Trop Med Parasitol 1975 69 2 155 171

Alqahtani

Kazi

Alsenaidy

Ahmad

Advances in oral drug delivery

Front Pharmacol 2021 12 618411

https://doi.org/10.3389/fphar.2021.618411

Shi

Chen

Zhang

Wang

Oral bioavailability comparison of artemisinin, deoxyartemisinin, and 10- deoxoartemisinin based on computer simulations and pharmacokinetics in rats

ACS Omega 2021 6 1 889 899

https://doi.org/10.1021/acsomega.0c05465

Klayman

Ager

Fleckenstein

Lin

Transdermal artelinic acid: an effective treatment for Plasmodium berghei-infected mice

Am J Trop Med Hyg 1991 45 5 602 607

https://doi.org/10.4269/ajtmh.1991.45.602

Lin

Ager

Jr Klayman

Antimalarial activity of dihydroartemisinin derivatives by transdermal application

Am J Trop Med Hyg 1994 50 6 777 783

https://doi.org/10.4269/AJTMH.1994.50.777

Figures and Tables

Fig. 1

N-89 plasma concentration after a single administration in mice. Mice received 75 mg/kg (po) or 30 mg/kg (iv). The dotted line indicated the EC₅₀ value of P. falciparum in vitro (6.8 ng/ml). The inset shows the structure of N-89.

Fig. 2

Antimalarial activity of N-89 (po, 75 mg/kg). Mice with more than 0.5% parasitemia, 75 mg/kg of N-89 administered 3 times daily for 3 days. The data are presented as the mean, with a bar indicating the SD value. A) Inset details the parasitemia from day 1 to 5. An arrow indicated the start time of the N-89 treatment.

Fig. 3

Antimalarial activity of N-89 (po, 50 mg/kg). Mice with more than 0.5% parasitemia, 50 mg/kg of N-89 administered thrice daily for 3 days. The data are presented as the mean, with a bar indicating the SD value. The inset details the parasitemia from day 1 to 6. An arrow indicated the start time of the N-89 treatment.

Table 1

Pharmacokinetic parameters of single administration of N-89 in mice

Dose (mg/kg)	t_1/2^a (h)	T_max^b (h)	C_max^c (mg/ml)	AUC_0→last^d (μg·h/ml)	AUC_0→∞^e (μg·h/ml)	V_dss^f (L/kg)	CL_tot^g (L/h/kg)	MRT^h (h)	Fⁱ (%)
30 (iv)	1.50			13.57	13.59	0.53	2.21	0.24
75 (po)	0.97	0.75	1.59	2.37	2.38			1.79	7.01

AUC and MRT were determined from the single-time course with mean values. All the reported data were expressed as the mean value (n=5).

^at_1/2, time required to reach half of C_max.

^bT_max, time required to reach the C_max.

^cC_max, highest detected plasma concentration of oral N-89.

^dAUC_{0 → last}, area under the plasma concentration-time curve from zero to the last observed concentration of N-89.

^eAUC_{0 → ∞}, area under the concentration–time curve from zero to infinity.

^fV_dss, volume of distribution at steady state.

^gCL_tot, total plasma clearance.

^hMRT, mean residence time.

ⁱF, bioavailability of N-89 calculated with 100×AUC_po×Dose_iv/AUC_iv×Dose_po.

Table 2

Antimalarial activity of N-89 using different administration routes

Route	Po^a		Iv^b		Sq^b,*
N-89 (mg/kg)	ED50	ED90	ED50	ED90	ED50	ED90
	20.5±2.0	43.5±1.5	14.5±1.9	21.0±0.8	2.5±1.1	3.8±1.0

^aSolvent; olive oil.

^bSolvent; ethanol: Cremophor EL: saline=1:1:8 (v/v/v).

^*N-89 (8 mg/kg) treated mice died on day 8 and the mean survival days of control mice was 6.5.

Data were represented as mean±SD value (n=5).

Table 3

Parasitemia of oral N-89 treated mice from days 1 to 6

	Day						MSD^d
	1	2	3	4	5	6	MSD^d
Control	0.10±0.10	0.68±0.17	5.86±1.01	24.10±2.80	46.70±5.50	58.9±11	5.6
N-89 (75 mg/kg)	0.09±0.07	0.70±0.19	0.26±0.05	0.01±0.01^a	0.00^b	0.00	>30
Control	0.07±0.02	0.44±0.11	3.26±1.51	15.64±6.06	44.28±6.44	56.98±8.78	6.2
N-89 (50 mg/kg)	0.10±0.04	0.51±0.14	0.11±0.06	0.01±0.01	0.002±0.004^c	0.00^b	>30

^aOne mouse cured with no parasites.

^bAll mice were cured.

^cFour mice were cured, and one mouse had 0.01% parasitemia. Parasitemia was represented as mean±SD value (n=5).

^dMSD, mean survival days.