The Fever Tree: from Malaria to Neurological Diseases.

This article describes the discovery and use of the South American cinchona bark and its main therapeutic (and toxic) alkaloids, quinine and quinidine. Since the introduction of cinchona to Europe in the 17th century, it played a role in treating emperors and peasants and was central to colonialism and wars. Over those 400 years, the medical use of cinchona alkaloids has evolved from bark extracts to chemical synthesis and controlled clinical trials. At the present time, the use of quinine and quinidine has declined, to a large extent due to their toxicity. However, quinine is still being prescribed in resource-limited settings, in severe malaria, and in pregnant women, and quinidine made a limited comeback in the treatment of several cardiac and neurological syndromes. In addition, the article presents more recent studies which improved our understanding of cinchona alkaloids' pharmacology. The knowledge gained through these studies will hopefully lead to a wider use of these drugs in precision medicine and to design of new generation, safer quinine and quinidine derivatives.

The Hidden History of a Famous Drug: Tracing the Medical and Public Acculturation of Peruvian Bark in Early Modern Western Europe (c. 1650-1720).

The history of the introduction of exotic therapeutic drugs in early modern Europe is usually rife with legend and obscurity and Peruvian bark is a case in point. The famous antimalarial drug entered the European medical market around 1640, yet it took decades before the bark was firmly established in pharmaceutical practice. This article argues that the history of Peruvian bark can only be understood as the interplay of its trajectories in science, commerce, and society. Modern research has mostly focused on the first of these, largely due to the abundance of medico-historical data. While appreciating these findings, this article proposes to integrate the medical trajectory in a richer narrative, by drawing particular attention to the acculturation of the bark in commerce and society. Although the evidence we have for these two trajectories is still sketchy and disproportionate, it can nevertheless help us to make sense of sources that have not yet been an obvious focus of research. Starting from an apparently isolated occurrence of the drug in a letter, this article focuses on Paris as the location where medical and public appreciation of the bark took shape, by exploring several contexts of knowledge circulation and medical practice there. These contexts provide a new window on the early circulation of knowledge of the bark, at a time when its eventual acceptance was by no means certain.

[Joseph-François Bourdier from La Moulière and his work in the five-year fever]. / Joseph-François Bourdier de La Moulière et ses travaux sur le quinquina fébrifuge (1809-1811).

J.-F. Bourdier was one of the doctors of the Faculty of Paris. As a medical doctor for the Archduchess Marie-Louise, he was also able to conduct his scientific research. In 1808, during the difficult time of the Continental System, J.-F. N. took part in the research work on a substitute for cinchona and tested some treatments. However, being not a chemist, he could not make any chemical analysis. Then, the chemists Caventou and Pelletier discovered quinine in 1820.

Dose-dependent resorption of quinine after intrarectal administration to children with moderate Plasmodium falciparum malaria.

The pharmacokinetics of increasing doses of an intrarectal Cinchona alkaloid combination containing 96.1% quinine, 2.5% quinidine, 0.68% cinchonine, and 0.67% cinchonidine (Quinimax) was compared to that of parenteral regimens in 60 children with moderate malaria. Quinine exhibited a nonlinear pharmacokinetics, suggesting a saturation of rectal resorption. When early rejections appeared, blood quinine concentrations decreased by 30 to 50% and were restored by an immediate half-dose administration of the drug. Rectal administration of doses of 16 or 20 mg/kg of body weight led to concentration-time profiles in blood similar to those of parenteral regimens and could be an early treatment of childhood malaria.

Phase I study of cinchonine, a multidrug resistance reversing agent, combined with the CHVP regimen in relapsed and refractory lymphoproliferative syndromes.

Overexpression of P-glycoprotein (P-gp) in cancer cells reduces intracellular accumulation of various anticancer drugs including anthracyclines and vinca alkaloids. This multidrug resistance (MDR) phenotype can be reversed in vitro by a number of non-cytotoxic drugs. We have identified the quinine's isomer cinchonine as a potent MDR reversing agent, both in vitro and in animal models. Here, we report an open phase I dose escalation trial in patients with refractory or relapsed malignant lymphoid diseases. Cinchonine dihydrochloride was administered by continuous i.v. infusion for 48 h and escalated over five dose levels ranging from 15 to 35 mg/kg/d. Cinchonine infusion started 24 h before i.v. doxorubicin (25 mg/m2), vinblastine (6 mg/m2), cyclophosphamide (600 mg/m2) and methylprednisolone (1 mg/kg/d) (CHVP regimen) and lasted for 24 h after chemotherapy infusion. Thirty-four patients received 87 cycles of CHVP/cinchonine. The MTD of cinchonine administered by continuous i.v. infusion was 30 mg/kg/d. Prolonged cardiac repolarization was the main dose-limiting toxicity. No ventricular arrhythmia including 'torsade de pointes' was observed. An MDR reversing activity was identified in the serum from every patient and correlated with cinchonine serum level. When infused at 30 mg/kg/d, cinchonine demonstrated a limited influence on doxorubicin pharmacokinetic. We conclude that i.v. infusion of cinchonine might be started 12 h before MDR-related chemotherapy infusion and requires continuous cardiac monitoring but no reduction of cytotoxic drug doses.

An open randomized clinical study of intrarectal versus infused Quinimax for the treatment of childhood cerebral malaria in Niger.

The intrarectal route has been shown to be an alternative to parenteral therapy for the treatment of acute uncomplicated malaria. We conducted an open randomized clinical study of intrarectal Quinimax (a Cinchona alkaloids association) (20 mg/kg, then 15 mg/kg every 8 h) vs. intravenous Quinimax (8 mg/ kg infused over 4 h every 8 h) for 2 d in 76 children (39 in the intrarectal and 37 in the infusion groups) with cerebral falciparum malaria in Niger. This treatment was followed by oral chloroquine (10 mg/kg/d for 3 d). The primary end points of the study were fatal outcome and coma recovery time. In the intrarectal group, 35 children were cured (90%) and 4 died. In the infused group, 28 were cured (76%) and 9 died; mean coma recovery times were 34.6 h (SD = 12.8) and 33.0 h (SD = 14.1) for the intrarectal and infused groups, respectively. None of the differences was significant. Both treatments were well tolerated and no anal irritation was observed with intrarectal Quinimax. These findings suggest that intrarectal Quinimax can be an alternative to intravenous administration for rapid onset childhood cerebral malaria in the rural tropics, where the safety of parenteral administration cannot be guaranteed.

Bitter-sweet solutions for malaria: exploring natural remedies from the past.

This paper explores "a wonderful cure" for malaria used successfully by Robert Talbor, an apothecary's apprentice in the English marshes, to treat Essex smugglers and European Royalty in the seventeenth century. The basis of this cure is identified as "quinquina" from the bark of the South American Cinchona tree. The story of Robert Talbor and his secret remedy for malaria opens up a set of intriguing questions about the early history of "quinquina", the subsequent development of quinine, the use of higher plants for antimalarial drugs, including the Chinese plant Artemisia annua L., and the value of unlocking the secrets of the past in our search for strategies to control malaria.

Plasmodium berghei mouse model: antimalarial activity of new alkaloid salts and of thiosemicarbazone and acridine derivatives.

Sixteen compounds were synthesized and evaluated on Plasmodium berghei in CD1 mouse. The nature of the salt associated to the active principle can give some advantages in the field of activity, bioavailability and toxicity. beta-Resorcylic acid was chosen in this study because of its previously described antimalarial activity and its expected enhancement of quinine antimalarial activity. While treatment with subcutaneous quinine sulphate at 1 mmol/kg cured 6/10 mice, quinine beta-resorcylate cured all the mice under identical conditions. Although such a result appeared promising, in vitro investigation should be performed to draw clear conclusions regarding a synergy between quinine and beta-resorcylate. Cinchonidine beta-resorcylate was also active; all mice were cured at 1 mmol/kg and the mean survival time was 13.8 +/- 2.4 days after a subcutaneous treatment at 0.5 mmol/kg in a single dose. In the series of acridines, (N-alpha, sigma-dioxopentyl)-5-amino-1,2,3,4-tetrahydroacridine cured all mice at 50 mumol/kg under the same conditions. The maximum tolerated doses in mice ranged from 100 to 150 mumol/kg for these acridine derivatives. The chemotherapeutic index of (N-alpha, sigma-dioxopentyl)-5-amino-1,2,3,4-tetrahydroacridine was estimated at 2-3. Other salts expected to reduce the toxicity, such as alpha-ketoglutarate and p-chlorophenoxyacetate, did not enhance the activity of the active principles. These results prompt us to further investigations including plasma kinetic evaluation in rats and in vitro on Plasmodium falciparum.

Intrarectal Quinimax (an association of Cinchona alkaloids) for the treatment of Plasmodium falciparum malaria in children in Niger: efficacy and pharmacokinetics.

In an attempt to avoid the complications associated with intramuscular quinine administration, we assessed the intrarectal route. Sixty-six children aged from 2 to 10 years with Plasmodium falciparum malaria were included in the study, which took place in Niamey, Niger. Fifty-five children were given 20 mg/kg of the diluted injectable form of Quinimax (a quinine, quinidine, cinchonine, cinchonidine association) intrarectally. A further 11 children with malaria were treated with 12.5 mg/kg of the same Quinimax solution by the intramuscular route. All the children were treated twice a day for 3 d. Blood samples were drawn from 20 children (15 treated intrarectally and 5 intramuscularly) for a kinetic study. Both modes of administration were well tolerated. Mean fever clearance times (+/- standard errors) were 48.6 +/- 2.7 h and 35.9 +/- 2.2 h in the intrarectal and intramuscular groups, respectively (P = 0.05). Mean parasite clearance times (+/- standard errors) and mean times to achieve 50% reduction in parasitaemia (+/- standard errors) were similar after intrarectal (46.5 +/- 5.7 h and 7.8 +/- 0.9 h respectively) and intramuscular administration (27.4 +/- 3.6 h and 8.7 +/- 1.7 h, respectively). Tmax. after intrarectal administration (2.7 +/- 0.4 h) did not differ significantly from the value after intramuscular administration (1.1 +/- 0.6 h), but Cmax. and the area under the concentration-time curve from 0 to 48 h were lower (4.9 +/- 0.6 mg/L and 230.0 +/- 9.6 mg/L.h, respectively) than after intramuscular administration (9.1 +/- 1.2 mg/L and 356.0 +/- 4.2 mg/L.h, respectively) (P < 0.001). Compared to the intramuscular route, intrarectal Quinimax bioavailability was 40%.(ABSTRACT TRUNCATED AT 250 WORDS)

Pharmacokinetics of quinine, quinidine and Cinchonine when given as combination.

Pharmacokinetics of quinine, quinidine and cinchonine when given as a combination were evaluated in Thai patients with falciparum malaria during acute infection and convalescence. The combination of quinine, quinidine and cinchonine was randomly given to thirteen patients at 400 mg or 600 mg (consisting of one-third of each component; 7 patients were enrolled in 400 mg regimen and 6 in 600 mg regimen) intravenously every 8 hours for 7 days. The drug combination was given again at day 35 to define the pharmacokinetics of each drug during convalescence. All patients with the 600 mg regimen had good response with 100% cure rate while patients with the 400 mg regimen had a good initial response but one patient recrudesed on day 46. This particular patient had plasma concentrations of all three drugs lower than the mean values of patients with sensitive responses. The plasma levels of quinine and quinidine obtained from the present study were higher than that expected from one-third of the conventional dose (600 mg) when given alone, suggesting drug combination interaction. The terminal half-lives of each of the three components were prolonged during acute malaria when compared to those obtained during convalescence.

Red cell and plasma concentrations of combined quinine-quinidine and quinine in falciparum malaria.

Red cell and plasma quinine-quinidine, and quinine concentrations in children with uncomplicated falciparum malaria who were treated with a combination of quinine/quinidine/cinchonine (combined drug) and quinine alone, respectively, were measured, using the extraction fluorescence method. The cure rates obtained with the high dose regimen of the combined drug (100%) were significantly higher than in the low dose regimen group (37.5%) (p less than 0.05), and the quinine regimen produced a 50% cure rate. Similar mild and transient ECG effects were noted in both the combined drug group and the quinine group. In patients treated with the combined drug, quinine-quinidine concentrations in both red cell and plasma of the high dose regimen group were significantly higher than those in the low dose regimen group (p less than 0.001, p less than 0.001). In quinine-treated patients, red cell quinine concentration in those with RII failure was significantly lower than that in patients with cure or RI failure (p less than 0.05). Both red cell and plasma levels of quinine-quinidine were higher than quinine levels. The red cell:plasma quinine-quinidine concentration ratios rose steadily to the high level from day 3 to day 6, while the ratio of quinine alone fluctuated around the low level and then gradually fell. The evidence suggests that red cell drug concentrations are more closely related to the outcome of treatment than to plasma concentrations and that the combined drug may be very useful for treatment of multi-drug-resistant P. falciparum infections. Further study is needed.

Combination of quinine, quinidine and cinchonine for the treatment of acute falciparum malaria: correlation with the susceptibility of Plasmodium falciparum to the cinchona alkaloids in vitro.

Thirteen patients with acute symptomatic uncomplicated falciparum malaria were enrolled in an open, randomized, phase 2, dose-finding clinical trial of a fixed dosage combination of quinine, quinidine and cinchonine (LA40221, Sanofi Recherche, France), which contained equal parts of the 3 alkaloids and was administered orally every 8 h in doses of 400 mg (7 patients) or 500 mg (6 patients) for 7 d. There was prompt clearance of parasitaemia and fever in all patients. The mean clearance times (+/- standard deviation) of parasitaemia, fever and other symptoms were 29 +/- 11.0 h, 10.7 +/- 4.1 h and 14.9 +/- 9.7 h respectively for the 400 mg dose group, and 35 +/- 20.0 h, 16 +/- 7.0 h and 17.6 +/- 8.7 h respectively for the 500 mg dose group. There was no recrudescence of parasitaemia during the 28 d observation period. Minor gastrointestinal side effects occurred in 2 patients, but there was no major side effect. Haematological, biochemical and other measurements were not adversely altered by treatment. QTc prolongation occurred in 3 patients--2 from the 400 mg and 1 from the 500 mg dose group. Testing in vitro against Plasmodium falciparum isolates from 47 patients (including the 13 patients enrolled in the trial) of the combination and its individual components suggested that the relative potencies in vitro, in decreasing order, were quinidine, LA40221, cinchonine and quinine. The minimum inhibitory concentrations were 0.32, 0.64, 0.64 and 1.28 mumol/litre of blood-medium mixture respectively, and the 50% inhibitory concentrations were 0.083, 0.11, 0.12 and 0.22 mumol/litre of blood-medium mixture. The respective 99% inhibitory concentrations were 0.27, 0.45, 0.50 and 1.20 mumol/litre of blood-medium mixture.