The importance of sarcolemmal-bound calcium (Ca) in the control of contraction in mammalian myocardium is indicated by the following results. The curve that relates [Ca]o (from 50 μM to 10 mM) to force development and that which relates [Ca]o to Ca bound to a highly purified sarcolemmal fraction are superimposable. The ability of a series of cations to uncouple excitation from contraction is the same as their relative ability to displace Ca from the sarcolemma. Dimethonium, which specifically displaces cation from the diffuse double layer of the cellular surface, has little effect on contractile force. This indicates that the Ca actually bound to the sarcolemma is the surface Ca important in contractile control. Polymyxin B, a highly charged cationic amphiphilic peptidolipid, specifically competes for Ca-binding sites on anionic and zwitterionic phospholipid. It is a potent displacer of Ca from myocardial cells and purified sarcolemma and a potent uncoupler. Phospholipase D cleaves the nitrogenous base from sarcolemmal phospholipid with production of anionic phosphatide acid. Phospholipase D treatment increases Ca bound to cells and purified sarcolemma and increases force development of ventricular tissue from both neonatal rat and adult rabbit. Insertion of charged amphiphiles in the sarcolemma as phospholipid analogues modulate interaction of Ca with the sarcolemma, e.g., anionic dodecylsulfate increases Ca bound to sarcolemmal vesicles by more than 80% and increases force development in rabbit papillary muscle by 100%. The effect of pH variation on Ca binding to phospholipid extracted from sarcolemma indicates that phospholipid accounts for at least 75% of the binding. The current model proposes a two-site control of Ca binding. One site, with pK in 6.0–7.0 range, controls access of Ca to a second site on phospholipid to which Ca binds. The access controlling sites may be amine groups; the binding sites are likely phosphate and (or) carboxyl groups.