The phylogenies of the cartilaginous fishes (class Chondrichthyes), and the subclasses Elasmobranchii (sharks and rays) and Holocephali (chimeras), are explained in detail by Klimley (2013) and Janvier and Pradel, (2015). In brief, the Elasmobranchii is separated into subgroups Selachii (sharks) and Batoidea (skates and rays), which show extraordinarily different body morphologies (e.g., the latter are dorso-ventrally flattened, have ventral gill slit openings, and pectoral fins fused to the side of the head forming wings). The modern sharks, in turn, are considered to have derived from two separate lineages: the squalomorphs (superorder Squalomorphi) and galeomorphs (superorder Galeomorphi), with the former considered the more primitive (Klimley, 2013). Since their major diversification in the Permian (∼250×10⁶ years ago), members of the Elasmobranchii have come to occupy almost all aquatic environments – from the surf zone of the continental shelves, to the brightly lighted surface water of the pelagic zone far from the continents, to abyssal depths (>3000 m), and even into freshwaters – and to occupy latitudes from the tropics to high Arctic (Klimley, 2013). Elasmobranchs also show a great diversity in life styles, life-histories, feeding strategies, energetics, etc. (Compagno, 1990). Given this great heterogeneity in gross body morphologies and ecologies, we contend that the cardiovascular systems of the ∼900–1000 extant species of cartilaginous fishes undoubtedly have a significant range in functional characteristics. Unfortunately, the functional properties of only a few elasmobranch species have been investigated, and these have largely been small, inshore, demersal species (e.g., catsharks, Scyliorhinus stellaris and S. canicula; epaulette shark, Hemiscyllium ocellatum; Port Jackson shark, Heterodontus portusjacksoni; eastern shovelnose ray, Aptychotrema rostrata; and spiny dogfish, Squalus acanthias and S. suckleyi). This situation occurs, in large measure, because studies on cardiovascular function generally require access to live specimens held in captivity, and species which are small enough to be easily and safely instrumented. As a result, our summary of cardiovascular function in elasmobranchs will largely rely on data from a relatively small number of generally inshore species that are primarily from temperate, and more occasionally from tropical, areas. We readily admit, therefore, that many of our conclusions may not be universally true for all extant elasmobranch species, but rather be applicable primarily to species sharing a recent common phylogeny, or those belonging to one of the ecomorphotype categories to which they can be assigned (Compagno, 1990).