Catheters and methods for intracardiac electrical mapping

What is claimed is: 1. A medical system comprising: a medical device defining a distal end including at least one array arm a plurality of treatment elements coupled to the at least one array arm, each treatment element having a mapping element protruding therefrom, at least a portion of each mapping element having an insulative layer that electrically isolates the mapping element from the treatment element; and a control unit in communication with the medical device, the control unit being configured to deliver electroporation energy to the plurality of electroporation treatment elements and being programmed to: assess a morphology of an electrical conduction of interest within cardiac tissue based on monophasic action potential signals received from the mapping elements; assess a directionality of the electrical conduction of interest based on signals received from the mapping elements; identify a source of the electrical conduction of interest based on the morphology and directionality of the electrical conduction of interest; determine and communicate to a user one or more optimal treatment sites; and disrupt the electrical conduction of interest by activating the plurality of treatment elements in at least one of the one or more optimal treatment sites, activating the plurality of treatment elements including delivering electroporation energy from the control unit to the plurality of electroporation treatment elements. 2. The system of claim 1 , wherein the plurality of mapping elements are arranged in a radially symmetrical pattern. 3. The system of claim 1 , wherein the one or more tissue areas are composed of cells and wherein the plurality of mapping elements selectively transmit energy capable of at least one of ablation and electroporation of the cells. 4. The system of claim 1 , wherein the one or more tissue areas are composed of cells and wherein the treatment element is configured to additionally transmit energy capable of at least one of adjusting the temperature of the one or more tissue areas to a sub-lethal temperature and ablating the one or more tissue areas. 5. The system of claim 1 , wherein the medical device defines a longitudinal axis, each of the at least one array arm including a first portion and a second portion, the first portion being in a plane that is substantially orthogonal to the longitudinal axis of the device. 6. The system of claim 1 , wherein each of the mapping elements records monophasic action potentials, such that at least one of depolarization timing, repolarization timing, action potential morphology, and action potential duration is unambiguously determined. 7. The system of claim 1 , wherein each mapping element has a curved surface. 8. The system of claim 1 , wherein each of the plurality of treatment elements includes a first portion that is at least partially wrapped around one of the at least one array arm and a second portion that extends a distance from the at least one array arm. 9. The system of claim 8 , wherein the mapping element protrudes from the first portion of the treatment element from which the mapping element protrudes. 10. A medical system comprising: a medical device defining a distal end including: at least one array arm; and a plurality of treatment elements coupled to the at least one array arm, each of the plurality of treatment elements having: a mapping element that protrudes from the treatment element and has a curved surface; a layer of insulation between the treatment element and the corresponding mapping element; a first portion that is at wrapped around at least a portion of the at least one array arm, the mapping element protruding from the first portion; and a second portion that extends a distance from the first portion; a control unit in communication with the medical device, the control unit being configured to deliver electroporation energy to the plurality of electroporation treatment elements and being programmed to: assess a morphology of an electrical conduction of interest within cardiac tissue based on monophasic action potential signals received from the mapping elements; assess a directionality of the electrical conduction of interest based on signals received from the mapping elements; identify a source of the electrical conduction of interest based on the morphology and directionality of the electrical conduction of interest; determine and communicate to a user one or more optimal treatment sites; and disrupt the electrical conduction of interest by activating the plurality of treatment elements in at least one of the one or more optimal treatment sites, activating the plurality of treatment elements including delivering electroporation energy from the control unit to the plurality of electroporation treatment.