Human malaria, one of the most striking, reemerging infectious diseases, is caused by several types
of Plasmodium parasites. As the parasite digests hemoglobin in human red blood cells, the heme byproduct crystallizes
into micron-sized malaria-pigment (hemozoin). Making use of a recently reported powder-crystal structure
determination of synthetic hemozoin (β-hematin), we describe here its theoretical growth form and show it to be
similar in habit and form to that of natural hemozoin. With this information, we propose a noncovalent binding site
for the quinoline drug family at the end face of the fastest-growing direction of β-hematin. This adsorption mechanism
is examined in terms of crystal growth inhibition vis-à-vis published data. The surface binding site elucidates the
difference in activity of various quinolines, revealing the importance of the different quinoline functionalities. The
interplay between molecular chirality of quinolines and the chirality of centrosymmetric β-hematin crystal faces is
analyzed in terms of crystal growth inhibition. We additionally propose a molecular isomerism of the crystalline
building blocks, with implications on quinoline surface binding, as well as on nucleation and size of β-hematin crystals.