For patients with end-stage kidney disease unable to receive a kidney transplant, replacement of kidney function with dialysis is necessary to extend life. Peritoneal dialysis (PD) and hemodialysis (HD) are the two major forms of dialysis therapy. HD involves the passage of blood via an extracorporeal circuit whereby removal of small solutes, toxins, and water is achieved across a synthetic, semipermeable dialysis membrane. In contrast, in PD, the dialysis membrane is the highly vascularized internal lining of the peritoneal cavity. Intraperitoneal installation of hypertonic high glucose PD solution creates a transmembrane osmotic and diffusive gradient that facilitates water removal [ultrafiltration (UF)], convection, and diffusion of uremic toxins. Insight into the physiology of solute and water transport across the peritoneal membrane has been enhanced by the proposal of the ''three-pore model'' of peritoneal membrane transport. Transport characteristics and UF capacity of the peritoneal membrane vary among individuals, and deleterious changes in the membrane may ensue over time. The degree to which these changes are a direct consequence of the type and composition of currently available PD solutions, recurrent infectious episodes, genetic differences among individuals, or a combination thereof is the subject of intense study. Adverse consequences resulting from the systemic and local metabolic effects of intraperitoneal glucose exposure, infection of the PD fluid, PD catheter dysfunction, and patient burnout from self-care often limit the long-term success of the therapy. Research aimed at addressing these challenges will examine the use of more biocompatible PD solutions and strategies aimed at attenuating progressive peritoneal membrane injury.