Basket catheter having insulated ablation electrodes and diagnostic electrodes

What is claimed is: 1 . An ablation system comprising: a catheter configured to be used in a medical procedure, the catheter comprising: a shaft extending along a longitudinal axis and comprising a distal tip; a plurality of electrically conductive splines coupled to the distal tip, each spline of the electrically conductive splines comprising an insulated portion and a non-insulated portion, the non-insulated portion being configured to make contact with a tissue of an anatomical structure and electrically ablate the tissue; an apex disposed at a distal end of the catheter, the plurality of electrically conductive splines being coupled to the apex and forming an expandable distal-end assembly between the distal tip of the shaft and the apex, wherein the apex comprises an insulated portion and an electrically conductive material disposed on the insulated portion, the electrically conductive material configured to make contact with tissue; and one or more electrodes coupled to the insulated portion of one or more splines of the plurality of electrically conductive splines, each of the one or more electrodes being configured to sense electrical signals in the tissue, and wherein the one or more electrodes are positioned to contact tissue simultaneously with the electrically conductive material of the apex; a generator; and a processor configured to: control ablation energy provided by the generator to the plurality of electrically conductive splines such that ablation energy is applied to a first spline of the plurality of electrically conductive splines without applying ablation energy to a second spline of the plurality of electrically conductive splines; and sense bipolar electrical signals in the tissue between an electrode of the one or more electrodes and the non-insulated portion of the apex. 2 . The catheter of claim 1 , wherein the electrically conductive material of the apex is further configured to deliver ablative energy to the tissue. 3 . The catheter of claim 1 , wherein an electrode of the one or more electrodes is defined by the electrically conductive material and coupled to the insulated portion of the apex. 4 . The catheter of claim 1 , further comprising: a bump stop coupled to a proximal side of the apex and separated from the distal tip by a collapsible gap. 5 . The catheter of claim 4 , wherein the bump stop is configured to contact the distal tip of the shaft to maintain a minimal distance between the apex and the distal tip of the shaft when a force is applied to the expandable distal-end assembly. 6 . The catheter of claim 4 , wherein the collapsible gap comprises a gap distance of about 3 mm as measured along the longitudinal axis when the expandable distal-end assembly is in an expanded position without force applied to the expandable distal-end assembly. 7 . The catheter of claim 1 , wherein at least 60 percent of a length at least one spline is non-insulated and is configured to make contact with tissue of the anatomical structure and to deliver ablative energy to the tissue. 8 . The catheter of claim 1 , wherein the plurality of electrically conductive splines are configured to ablate an area of about 256 mm 2 of the tissue. 9 . The catheter of claim 1 , wherein the non-insulated portion of each spline of the plurality of electrically conductive splines measures between about 10 mm and about 40 mm. 10 . The catheter of claim 1 , wherein the shaft is configured to be manipulated to position the plurality of electrically conductive splines within the anatomical structure, wherein the anatomical structure comprises a heart of a patient, wherein the non-insulated portions of the plurality of electrically conductive splines are configured to deliver radiofrequency and/or irreversible electroporation pulses to deliver ablative energy to tissue of the heart. 11 . An ablation system comprising: a catheter comprising: a shaft, a plurality of electrically conductive splines coupled to a distal end of the shaft, an apex disposed at a distal end of the catheter, the plurality of electrically conductive splines being coupled to the apex and forming an expandable distal-end assembly between a distal tip of the shaft and the apex, wherein the apex comprises an insulated portion and a non-insulated portion, the non-insulated portion configured to make contact with tissue, and one or more electrodes coupled to an insulated portion of one or more splines of the plurality of electrically conductive splines and positioned such that the one or more electrodes are configured to contact the tissue simultaneously with the non-insulated portion of the apex; a generator; and a processor configured to: control ablation energy provided by the generator to the plurality of electrically conductive splines such that ablation energy is applied to a first spline of the plurality of electrically conductive splines without applying ablation energy to a second spline of the plurality of electrically conductive splines, and sense bipolar electrical signals in the tissue between an electrode of the one or more electrodes and the non-insulated portion of the apex. 12 . The ablation system of claim 11 , wherein each spline of the electrically conductive splines comprises a non-insulated portion, the non-insulated portion being configured to make contact with the tissue of an anatomical structure and electrically ablate the tissue. 13 . The ablation system of claim 12 , wherein the non-insulated portion of each spline of the plurality of electrically conductive splines measures between about 10 mm and about 40 mm. 14 . The ablation system of claim 12 , wherein the shaft is configured to be manipulated to position the plurality of electrically conductive splines within an anatomical structure, wherein the anatomical structure comprises a heart of a patient, wherein the non-insulated portions of the plurality of electrically conductive splines are configured to deliver radiofrequency and/or irreversible electroporation pulses to deliver ablative energy to tissue of the heart. 15 . The ablation system of claim 11 , wherein the catheter comprises a bump stop coupled to a proximal side of the apex and separated from the distal tip by a collapsible gap. 16 . The ablation system of claim 15 , wherein the bump stop is configured to contact the distal tip of the shaft to maintain a minimal distance between the apex and the distal tip of the shaft when a force is applied to the expandable distal-end assembly. 17 . The ablation system of claim 16 , wherein the shaft extends along a longitudinal axis and the collapsible gap comprising a gap distance of about 3 mm as measured along the longitudinal axis is provided when the expandable distal-end assembly is in an expanded position without force applied to the expandable distal-end assembly. 18 . The ablation system of claim 11 , wherein at least 60 percent of a length at least one spline is non-insulated and is configured to make contact with the tissue to deliver ablative energy to the tissue. 19 . The ablation system of claim 11 , wherein the plurality of electrically conductive splines are configured to ablate an area of about 256 mm 2 of the tissue. 20 . The ablation system of claim 11 , wherein the non-insulated portion of the apex is further configured to deliver ablative energy to the tissue.