5 research outputs found
Quinolone-based compounds, formulations, and uses thereof
Provided herein are quinolone-based compounds that can be used for treatment and/or prevention of malaria and formulations thereof. Also provided herein are methods of treating and/or preventing malaria in a subject by administering a quinolone-based compound or formulation thereof provided herein
Design and Synthesis of Orally Bioavailable Piperazine Substituted 4(1H)-Quinolones with Potent Antimalarial Activity: Structure–Activity and Structure–Property Relationship Studies
Malaria deaths have been decreasing over the last 10–15 years, with global mortality rates having fallen by 47% since 2000. While the World Health Organization (WHO) recommends the use of artemisinin-based combination therapies (ACTs) to combat malaria, the emergence of artemisinin resistant strains underscores the need to develop new antimalarial drugs. Recent in vivo efficacy improvements of the historical antimalarial ICI 56,780 have been reported, however, with the poor solubility and rapid development of resistance, this compound requires further optimization. A series of piperazine-containing 4(1H)-quinolones with greatly enhanced solubility were developed utilizing structure–activity relationship (SAR) and structure–property relationship (SPR) studies. Furthermore, promising compounds were chosen for an in vivo scouting assay to narrow selection for testing in an in vivo Thompson test. Finally, two piperazine-containing 4(1H)-quinolones were curative in the conventional Thompson test and also displayed in vivo activity against the liver stages of the parasite
ICI 56,780 Optimization: Structure–Activity Relationship Studies of 7‑(2-Phenoxyethoxy)-4(1<i>H</i>)‑quinolones with Antimalarial Activity
Though
malaria mortality rates are down 48% globally since 2000,
reported occurrences of resistance against current therapeutics threaten
to reverse that progress. Recently, antimalarials that were once considered
unsuitable therapeutic agents have been revisited to improve physicochemical
properties and efficacy required for selection as a drug candidate.
One such compound is 4Â(1<i>H</i>)-quinolone ICI 56,780,
which is known to be a causal prophylactic that also displays blood
schizonticidal activity against <i>P. berghei.</i> Rapid
induction of parasite resistance, however, stalled its further development.
We have completed a full structure–activity relationship study
on 4Â(1<i>H</i>)-quinolones, focusing on the reduction of
cross-resistance with atovaquone for activity against the clinical
isolates W2 and TM90-C2B, as well as the improvement of microsomal
stability. These studies revealed several frontrunner compounds with
superb in vivo antimalarial activity. The best compounds were found
to be curative with all mice surviving a <i>Plasmodium berghei</i> infection after 30 days
ICI 56,780 Optimization: Structure–Activity Relationship Studies of 7‑(2-Phenoxyethoxy)-4(1<i>H</i>)‑quinolones with Antimalarial Activity
Though
malaria mortality rates are down 48% globally since 2000,
reported occurrences of resistance against current therapeutics threaten
to reverse that progress. Recently, antimalarials that were once considered
unsuitable therapeutic agents have been revisited to improve physicochemical
properties and efficacy required for selection as a drug candidate.
One such compound is 4Â(1<i>H</i>)-quinolone ICI 56,780,
which is known to be a causal prophylactic that also displays blood
schizonticidal activity against <i>P. berghei.</i> Rapid
induction of parasite resistance, however, stalled its further development.
We have completed a full structure–activity relationship study
on 4Â(1<i>H</i>)-quinolones, focusing on the reduction of
cross-resistance with atovaquone for activity against the clinical
isolates W2 and TM90-C2B, as well as the improvement of microsomal
stability. These studies revealed several frontrunner compounds with
superb in vivo antimalarial activity. The best compounds were found
to be curative with all mice surviving a <i>Plasmodium berghei</i> infection after 30 days
Design and Synthesis of Orally Bioavailable Piperazine Substituted 4(1<i>H</i>)‑Quinolones with Potent Antimalarial Activity: Structure–Activity and Structure–Property Relationship Studies
Malaria deaths have been decreasing
over the last 10–15
years, with global mortality rates having fallen by 47% since 2000.
While the World Health Organization (WHO) recommends the use of artemisinin-based
combination therapies (ACTs) to combat malaria, the emergence of artemisinin
resistant strains underscores the need to develop new antimalarial
drugs. Recent in vivo efficacy improvements of the historical antimalarial
ICI 56,780 have been reported, however, with the poor solubility and
rapid development of resistance, this compound requires further optimization.
A series of piperazine-containing 4Â(1<i>H</i>)-quinolones
with greatly enhanced solubility were developed utilizing structure–activity
relationship (SAR) and structure–property relationship (SPR)
studies. Furthermore, promising compounds were chosen for an in vivo
scouting assay to narrow selection for testing in an in vivo Thompson
test. Finally, two piperazine-containing 4Â(1<i>H</i>)-quinolones
were curative in the conventional Thompson test and also displayed
in vivo activity against the liver stages of the parasite