Ablation catheter with selective radial energy delivery

What is claimed is: 1. An electrode assembly configured to be disposed longitudinally over a distal portion of a cylindrical catheter body proximal to a tip of the catheter body, the electrode assembly comprising: a flexible substrate forming a cylinder over the distal portion of the cylindrical catheter body proximal the tip, the cylindrical flexible substrate having: i) a first independently controlled ablation electrode formed by a first longitudinal electrically conducting layer applied directly to the outer surface of the cylindrical flexible substrate, ii) a second independently controlled ablation electrode formed by a second longitudinal electrically conducting layer applied directly to the outer surface of the cylindrical flexible substrate, iii) a first plurality of associated microelectrodes formed within a perimeter of the first ablation electrode, wherein an empty space is disposed between the first ablation electrode and at least one microelectrode of the first plurality of microelectrodes, and iv) a second plurality of associated microelectrodes formed within a perimeter of the second ablation electrode, wherein the first and second ablation electrodes and their associated microelectrodes, respectively, are positioned diametrically opposed to each other circumferentially on the cylindrical flexible substrate. 2. The electrode assembly of claim 1 , comprising more than two ablation electrodes. 3. The electrode assembly of claim 1 , wherein at least some of the microelectrodes are configured to sense tissue contact. 4. The electrode assembly of claim 1 , wherein at least some of the microelectrodes are temperature sensors. 5. The electrode assembly of claim 1 , wherein each ablation electrode has a plurality of apertures configured to perfuse irrigation fluid. 6. A method for the ablation of a portion of tissue of a patient by an operator comprising: inserting a catheter into the patient, wherein the catheter comprises: an elongated cylindrical body having a distal portion proximal to a tip; and an electrode assembly disposed longitudinally over the distal portion of the cylindrical elongated body proximal the tip, wherein the electrode assembly comprises a flexible substrate forming a cylinder over the distal portion of the cylindrical catheter body proximal the tip, the cylindrical flexible substrate having: i) a first independently controlled ablation electrode formed by a first longitudinal electrically conducting layer applied directly to the outer surface of the cylindrical flexible substrate, ii) a second independently controlled ablation electrode formed by a second longitudinal electrically conducting layer applied directly to the outer surface of the cylindrical flexible substrate, iii) a first plurality of associated microelectrodes formed within a perimeter of the first ablation electrode, wherein an empty space is disposed between the first ablation electrode and at least one microelectrode of the first plurality of microelectrodes, and iv) a second plurality of associated microelectrodes formed within a perimeter of the second ablation electrode, wherein the first and second ablation electrodes and their associated microelectrodes, respectively, are positioned diametrically opposed to each other circumferentially on the cylindrical flexible substrate; connecting the catheter to a system controller capable of selectively delivering power to at least one of the ablation electrodes; and controlling the power to at least one of the ablation electrodes to ablate the portion of the tissue. 7. The method of claim 6 , wherein controlling the power to at least one of the ablation electrodes causes the electrode assembly to preferentially emit energy in a radial direction. 8. The method of claim 6 , further comprising receiving signals from a plurality of microelectrodes of the electrode assembly, wherein at least some of the microelectrodes are configured to sense tissue and wherein controlling the power to at least one of the ablation electrodes is based at least in part on the received signals.