Keyphrases
In Silico Assessment
100%
Lipid Fingerprint
100%
Computational Biophysics
100%
Structural Information
100%
Plasmodium Falciparum
100%
Malaria Parasite
100%
P4-ATPase
100%
Phosphatidylinositol
100%
Probenecid
100%
TRPV2
100%
Vasodilator
100%
Coarse-grained Molecular Dynamics
50%
Plasmodium Chabaudi
50%
Protein-lipid Interactions
50%
Orthologs
50%
Lipids
50%
Conserved Residues
50%
Evolutionary
50%
Plasmodium Species
50%
P-type ATPase
50%
Phosphatidylinositol-4-phosphate
50%
Binding Pocket
50%
Allosteric Binding Site
50%
Lipid Membrane
50%
Antimalarial Target
50%
Phospholipids
50%
Benzoic Acid
22%
Sulfonyl
22%
Piperidine
22%
EC50
22%
Binding Site
22%
Piperlongumine
11%
Vascular Relaxation
11%
Chemical Similarity
11%
Unbiased Data
11%
Neuromuscular Function
11%
Muscular Dystrophy
11%
Pharmacology
11%
Drug Target
11%
Data Analysis Methods
11%
Unsupervised Analysis
11%
Hypertensive
11%
Medium Throughput
11%
Physiopathology
11%
Similarity-based
11%
Pichia Pastoris
11%
Metabolism
11%
Gaussian Accelerated Molecular Dynamics (GaMD)
11%
Female Mice
11%
Cheminformatics
11%
Biochemistry, Genetics and Molecular Biology
Plasmodium
100%
ATPase
100%
Lipid
100%
TRPV2
100%
Agonist
100%
Phosphatidylinositol
66%
Binding Site
66%
Dynamics
44%
P-Type ATPase
33%
Orthology
33%
Evolution
33%
Plasmodium falciparum
33%
Plasmodium chabaudi
33%
Membrane Lipid
33%
Phosphatidylinositol 4-Phosphate
33%
Phospholipid
33%
Life Cycle
33%
Protein-Lipid Interaction
33%
EC50
22%
Sulfonyl
22%
Fungal Membrane
11%
Komagataella pastoris
11%
Neuromuscular Function
11%
Membrane Protein
11%
Metabolic Pathway
11%
Gaussian Distribution
11%
Heart Function
11%
Transient Receptor Potential Channel
11%
Ligand Binding
11%
Pharmacology, Toxicology and Pharmaceutical Science
Probenecid
100%
Vasodilator Agent
100%
Binding Site
60%
Sulfonyl
40%
Benzoic Acid
40%
Piperidine
40%
EC50
40%
Membrane Protein
20%
Pathophysiology
20%
Calcium Ion
20%
Muscular Dystrophy
20%
Komagataella pastoris
20%
Antihypertensive Agent
20%
Malignant Neoplasm
20%
Orphan Drug
20%
Transient Receptor Potential Channel
20%