JPWO2020257763A5 - - Google Patents

Description

Any of the methods in any of these additional methods may be used with any of the catheters in these additional examples. Any of these additional example catheters may be used with the methods described herein and may be used in ways not described herein.
[Appendix 1]
1. A method of positioning an ablation catheter in a T9, T10, or T11 intercostal vein at a location for ablating the greater splanchnic nerve (GSN), comprising:
imaging a portion of a patient including at least one of the T9, T10, or T11 intercostal veins and a portion of the patient's spine;
positioning a distal section of an ablation catheter in the T9, T10, or T11 intercostal vein;
ablation catheter radiopaque markers in one or more of the portion of the spine, ribs, costovertebral joints, azygos veins, or venous ostia between the azygos veins and the T9, T10, or T11 intercostal veins; positioning a location based on the position of the radiopaque marker relative to;
delivering energy from an ablation catheter ablation element;
method including.
[Appendix 2]
Clause 1. The method of Clause 1, wherein the step of positioning the radiopaque marker comprises positioning the radiopaque marker at the midline of the spine.
[Appendix 3]
3. The method of Clause 2, wherein the radiopaque marker is proximal to the ablation element.
[Appendix 4]
Based on the imaging, if the venous ostium is biased to the left relative to the midline of the spine, move the radiopaque marker distally to the midline of the spine. 3. The method of Clause 2, further comprising advancing.
[Appendix 5]
Clause 1. The method of Clause 1, wherein the step of positioning the radiopaque marker comprises positioning the radiopaque marker within the venous ostium.
[Appendix 6]
Clause 6. The method of Clause 5, wherein the radiopaque marker is proximal to the ablation element.
[Appendix 7]
2. The method of Claim 1, wherein the step of positioning the radiopaque marker comprises determining whether the azygos vein is biased to the left based on the imaging.
[Appendix 8]
8. The method of Claim 7, wherein the radiopaque marker is positioned at or near the midline of the spine if the azygos vein is skewed to the left.
[Appendix 9]
2. The method of Claim 1, wherein the step of positioning the radiopaque marker comprises determining whether the azygos vein is biased to the right based on the imaging.
[Appendix 10]
The step of positioning the radiopaque marker moves the radiopaque marker relative to at least one of the costovertebral joint or the rib if the azygos vein is skewed to the right. Clause 9. The method of clause 9, comprising the step of targetally positioning.
[Appendix 11]
11. The method of Clause 10, wherein the radiopaque marker is distal to the ablation element.
[Appendix 12]
further comprising withdrawing the ablation catheter proximally if the radiopaque marker is located too far distally relative to the rib or costovertebral joint. 9. The method according to 9.
[Appendix 13]
The step of positioning the radiopaque marker positions the radiopaque marker at a location based on the relative position of the radiopaque marker and at least one of the rib or the costovertebral joint. The method of clause 1, comprising
[Appendix 14]
2. The method of Claim 1, wherein the step of positioning the radiopaque marker comprises positioning the radiopaque marker at a location based on the relative position of the radiopaque marker and the midline of the spine. the method of.
[Appendix 15]
The step of positioning the radiopaque marker includes at least one of the radiopaque marker and the azygos vein or the venous ostia between the azygos vein and the T9, T10, or T11 intercostal vein. 2. The method of clause 1, comprising positioning the radiopaque marker at a location based on the relative positions of one and the other.
[Appendix 16]
Clause 1. The method of Clause 1, wherein the radiopaque marker is proximal to the ablation element.
[Appendix 17]
Clause 1. The method of Clause 1, wherein the radiopaque marker is distal to the ablation element.
[Appendix 18]
The step of positioning the radiopaque marker allows the GSN to be ablated while minimizing the risk of damaging at least one non-target structure by delivering energy from the ablation catheter ablation element. Clause 1. The method of Clause 1, wherein the ablation element is positioned in a location to enhance .
[Appendix 19]
19. The method of Clause 18, wherein the at least one non-target structure includes at least one of a sympathetic nerve trunk, vagus nerve, thoracic duct, or esophagus.
[Appendix 20]
19. The method of Clause 18, wherein the step of positioning the radiopaque marker positions the ablation element proximal to a sympathetic nerve trunk.
[Appendix 21]
19. The method of Clause 18, wherein the step of positioning the radiopaque marker positions the ablation element between the ostium of the vein and the sympathetic trunk.
[Appendix 22]
Clause 1. The method of Clause 1, wherein the step of delivering energy is performed after determining that the radiopaque marker is at or proximal to the rib or costovertebral joint.
[Appendix 23]
Clause 1. The method of Clause 1, further comprising moving the ablation element proximally if the radiopaque marker is neither on the rib nor on the costovertebral joint or proximal thereof.
[Appendix 24]
Clause 1. The method of Clause 1, wherein the ablation element is a proximal ablation element and the ablation catheter further comprises a distal ablation element.
[Appendix 25]
Clause 25. The method of Clause 24, wherein no energy is delivered from the distal ablation element if the radiopaque marker is relatively too distal within the intercostal vein.
[Appendix 26]
Clause 1. The method of Clause 1, wherein the ablation element includes first and second axially-spaced coiled electrodes.
[Appendix 27]
The ablation element includes a coiled ablation electrode, and the step of positioning the radiopaque marker aligns the distal end of the coiled ablation electrode with the venous ostium in the T9, T10, or T11 intercostal vein. 2. The method of claim 1, wherein the positioning is within 30 mm from
[Appendix 28]
moving the ablation element to another of the T9, T10, or T11 intercostal veins; and delivering energy from the ablation element in the other vein after the moving step. The method of clause 1, comprising:
[Appendix 29]
Clause 1. The method of Clause 1, further comprising accessing venous vasculature in the patient's jugular or femoral veins with an access introducer sheath.
[Appendix 30]
30. The method of paragraph 29, further comprising delivering a delivery sheath to the azygos vein to a chest level above the T9, T10, or T11 intercostal vein.
[Appendix 31]
Clause 1. The method of Clause 1, further comprising delivering a guidewire through the delivery sheath and into the T9, T10, or T11 intercostal vein.
[Appendix 32]
32. The method of Clause 31, further comprising delivering the ablation catheter through the delivery sheath over the guidewire.
[Appendix 33]
Clause 1. The method of Clause 1, further comprising delivering a radiopaque contrast agent from the ablation catheter to display the location of the azygos vein and the T9, T10, or T11 intercostal vein during the imaging step. .
[Appendix 34]
10. The method of Clause 1, wherein the imaging step comprises imaging in an anterior oblique view.
[Appendix 35]
Clause 1. The method of Clause 1, wherein the imaging step comprises imaging in an anterior-posterior direction.
[Appendix 36]
Clause 1. The method of Clause 1, wherein the imaging step comprises positioning the C-arm at a right anterior oblique angle.
[Appendix 37]
37. The method of clause 36, wherein said positioning step comprises positioning said C-arm between 20 and 70 degrees (optionally between 30 and 60 degrees).
[Appendix 38]
the positioning step includes positioning the C-arm at an angle that maximizes a projected distance between first and second axially-spaced locations on the ablation catheter; 36. The method of Appendix 36.
[Appendix 39]
The positioning step positions the C-arm at an angle that maximizes the projected distance between first and second axially-spaced radiopaque markers. 39. The method of clause 38, comprising
[Appendix 40]
Clause 1. The method of Clause 1, wherein delivering energy from the ablation element comprises delivering one or more of radio frequency energy, ultrasonic energy, chemical energy, thermal energy, or electroporation energy.
[Appendix 41]
Clause 1. The method of Clause 1, wherein the ablation energy source is in communication with a computerized controller.
[Appendix 42]
an algorithm stored in the computerized controller, the algorithm configured to identify whether at least a portion of the ablation element is located within the azygos vein; 42. The method of clause 41, configured to adjust one or more energy delivery parameters based on said position.
[Appendix 43]
Clause 1. The clause 1, wherein the ablation energy is RF and the computerized controller is adapted to deliver RF power in the range of 15W-50W (eg, 15-40W, such as 20-35W). Method.
[Appendix 44]
44. The method of Clause 43, wherein the RF energy is delivered to a first electrode and then delivered to a second electrode.
[Appendix 45]
44. The method of Clause 43, wherein the RF energy is delivered to the first electrode and the second electrode simultaneously, but are pulsed and asynchronous so that they are independent of each other.
[Appendix 46]
46. The method of clause 45, wherein said pulse width is in the range of 1-2 seconds.
[Appendix 47]
44. The method of Clause 43, wherein RF is delivered in bipolar mode between the first electrode and the second electrode.
[Appendix 48]
Said ablation energy is RF, and a computerized controller applies RF power over 20-120 seconds, such as over 50-120 seconds, such as over 90-120 seconds, such as over 90 seconds, over 100 seconds, over 110 seconds , or over 120 seconds).
[Appendix 49]
Clause 1. The method of Clause 1, further comprising directing irrigation to one or more ablation catheter irrigation ports at a flow rate of 10-20 mL/min (eg, 15 mL/min).
[Appendix 50]
The ablation catheter has one or more irrigation ports in fluid communication with an irrigation lumen, the irrigation lumen is connectable to an irrigation source (e.g., saline and, optionally, a pump); Clause 1. The method of Clause 1, further comprising delivering an irrigation fluid (eg, saline) from the ablation catheter in proximity to the RF electrode.
[Appendix 51]
51. The method of Clause 50, wherein the step of delivering the irrigation fluid can be performed while advancing the ablation element into an intercostal vein to facilitate the advancement into the intercostal vein. .
[Appendix 52]
51. The method of Clause 50, wherein the step of delivering the irrigation fluid can be performed while removing the ablation element from the intercostal vein to facilitate removal of the ablation element.
[Appendix 53]
Clause 1. The method of Clause 1, further comprising confirming that the ablation was successful.
[Appendix 54]
The steps of confirming successful ablation include performing baseline tests to assess parameters such as venous compliance, heart rate, vasoconstriction, or blood pressure; 54. The method of Clause 53, comprising the step of conducting a test.
[Appendix 55]
54. The method of Clause 53, wherein confirming successful ablation includes evaluating whether the magnitude of change in the parameter exceeds a threshold.
[Appendix 56]
The step of confirming successful ablation includes delivering neural stimulation signals from one or more stimulation electrodes on the ablation catheter before and after the steps of delivering ablation energy and evaluating parameters. 56. The method of clause 55, comprising
[Appendix 57]
moving the ablation catheter to another one of the T9, T10, or T11 intercostal veins; and delivering ablation energy in the other one of the T9, T10, or T11 intercostal veins. Clause 1. The method of Clause 1, further comprising:
[Appendix 58]
The method of any one of Clauses 1-57, comprising using any of the ablation catheters of Clauses 59-148.
[Appendix 59]
1. An ablation catheter for transvascular ablation of the thoracic splanchnic nerve, in particular for ablating the greater splanchnic nerve or the greater splanchnic nerve root, comprising:
an elongated shaft, said elongated shaft having a length such that a distal section of said elongated shaft can be placed in a T9, T10, or T11 intercostal vein; said elongated shaft, wherein the distal section has an outer diameter of 1.5-3 mm;
An electrically conductive flexible proximal ablation electrode and a distal ablation electrode mounted on the elongated shaft distal section from the distal end of the distal electrode to the proximal end of the proximal electrode. said proximal ablation electrode and said distal ablation electrode having a length of 10-25 mm, said proximal electrode and said distal electrode each having a length of 5-12 mm;
an axial spacing of 0.1-2 mm between the proximal ablation electrode and the distal ablation electrode;
a distal radiopaque marker positioned 0-5 mm distal to the distal end of the distal electrode;
a proximal radiopaque marker positioned 0-5 mm proximal to the proximal end of the proximal electrode;
an ablation catheter including;
[Appendix 60]
60. The catheter of paragraph 59, wherein the length from the distal end of the distal electrode to the proximal end of the proximal electrode is 15-20 mm.
[Appendix 61]
60. The catheter of paragraph 59, wherein the proximal electrode and the distal electrode are each 7-9 mm (eg, 7 mm, 7.5 mm, 8 mm, 8.5 mm, or 9 mm) in length.
[Appendix 62]
60. The ablation catheter of paragraph 59, wherein the distal ablation electrode and the proximal ablation electrode are axially spaced apart by 0.5-1 mm.
[Appendix 63]
60. The ablation catheter of paragraph 59, wherein the distal ablation electrode and the proximal ablation electrode are the same length.
[Appendix 64]
60. The ablation catheter of Clause 59, wherein the distal ablation electrode and the proximal ablation electrode are not the same length.
[Appendix 65]
60. The ablation catheter of clause 59, wherein the distal ablation electrode and the proximal ablation electrode are each 6-10 mm in length.
[Appendix 66]
Clause 59. The ablation catheter of Clause 59, wherein the distal ablation electrode has a helical configuration and the proximal ablation electrode has a helical configuration.
[Appendix 67]
Clause 67. The ablation catheter of Clause 66, wherein the helical configurations of the distal ablation electrode and the proximal ablation electrode are the same.
[Appendix 68]
Clause 67. The ablation catheter of Clause 66, wherein the helical configurations of the distal ablation electrode and the proximal ablation electrode have one or more different characteristics.
[Appendix 69]
69. The catheter of clause 68, wherein the one or more different characteristics include one or more of coil orientation (eg, left-handed or right-handed), pitch, or thickness.
[Appendix 70]
60. The catheter of paragraph 59, wherein the distal ablation electrode and the proximal ablation electrode each have a curvilinear cross-sectional configuration.
[Appendix 71]
60. The catheter of paragraph 59, wherein the distal ablation electrode and the proximal ablation electrode each have a rectilinear cross-sectional configuration.
[Appendix 72]
60. The catheter of paragraph 59, wherein the distal ablation electrode and the proximal ablation electrode are made from a superelastic material such as Nitinol.
[Appendix 73]
The distal ablation electrode and the proximal ablation electrode have sufficient flexibility and size to allow the distal section to be advanced from the azygos vein into one of the T9, T10, or T11 intercostal veins. 60. The catheter of paragraph 59, comprising:
[Appendix 74]
The distal and proximal ablation electrodes are affixed to distal and proximal end regions of the shaft, respectively, but between the distal and proximal end regions 60. The catheter of paragraph 59, which is not glued.
[Appendix 75]
60. The catheter of paragraph 59, further comprising radiopaque markers.
[Appendix 76]
76. The catheter of paragraph 75, wherein the radiopaque marker is located distal to the distal end of the distal ablation electrode.
[Appendix 77]
77. The catheter of paragraph 76, wherein the radiopaque marker is 0-5 mm (optionally 0-3 mm) distal to the distal end of the distal ablation electrode.
[Appendix 78]
76. The catheter of paragraph 75, wherein the radiopaque marker is located proximal to the proximal end of the proximal ablation electrode.
[Appendix 79]
79. The catheter of paragraph 78, wherein the radiopaque marker is 0-5 mm (optionally 0-3 mm) proximal to the proximal end of the distal ablation electrode.
[Appendix 80]
60. The catheter of paragraph 59, wherein each of the distal ablation electrode and the proximal ablation electrode are not configured to deploy to a deployed configuration.
[Appendix 81]
60. The catheter of paragraph 59, wherein the distal ablation electrode and the proximal ablation electrode each have an operational configuration that is the same or approximately the same as a delivery configuration.
[Appendix 82]
60. The catheter of paragraph 59, wherein the distal ablation electrode and the proximal ablation electrode each have an outer diameter in the operational state that is the same as or approximately the same as an outer diameter in the delivery state.
[Appendix 83]
60. The catheter of paragraph 59, wherein the distal ablation electrode and the proximal ablation electrode each have an expanded configuration that differs from a delivery configuration.
[Appendix 84]
60. The catheter of paragraph 59, further comprising a temperature sensor mounted on said shaft.
[Appendix 85]
85. The catheter of paragraph 84, wherein the temperature sensor is located at the distal end of the distal ablation electrode.
[Appendix 86]
85. The catheter of paragraph 84, wherein the temperature sensor is located at the proximal end of the proximal ablation electrode.
[Appendix 87]
further comprising a second temperature sensor, said temperature sensor positioned at the distal end of said distal ablation element and said second temperature sensor positioned at said proximal end of said proximal ablation element; 84. The catheter of paragraph 84.
[Appendix 88]
60. The catheter of paragraph 59, further comprising one or more irrigation ports in fluid communication with an irrigation lumen, said irrigation lumen connectable to a fluid source at a proximal region of said ablation catheter.
[Appendix 89]
89. The catheter of paragraph 88, wherein one of the one or more irrigation ports is axially between the distal ablation electrode and the proximal ablation electrode.
[Appendix 90]
89. The catheter of paragraph 88, wherein none of the one or more irrigation ports are radially disposed below the ablation electrode structure.
[Appendix 91]
89. The catheter of paragraph 88, wherein the one or more irrigation ports are positioned between helical windings of the distal ablation electrode and the proximal ablation electrode.
[Appendix 92]
92. The catheter of paragraph 91, wherein none of the one or more irrigation ports are radially disposed below the ablation electrode structure.
[Appendix 93]
89. The catheter of paragraph 88, wherein an irrigation port is positioned between every adjacent pair of ablation electrode helical sections of the distal and proximal ablation electrodes when viewed from the side.
[Appendix 94]
60. The catheter of paragraph 59, wherein the distal ablation electrode and the proximal ablation electrode are electrically configured to be individually energized in monopolar mode.
[Appendix 95]
60. The catheter of paragraph 59, wherein the distal ablation electrode and the proximal ablation electrode are electrically configured to be energized in bipolar mode.
[Appendix 96]
60. The catheter of paragraph 59, wherein the distal section is within 7 cm of the distal tip of the ablation catheter, optionally wherein the distal section has a straight rest configuration.
[Appendix 97]
60. The ablation catheter of clause 59, wherein the distal ablation electrode and the proximal ablation electrode are adapted to create continuous ablations ranging in length from 10-25 mm (eg, 15-20 mm).
[Appendix 98]
60. The ablation catheter of paragraph 59, wherein the distal section is adapted to flexibly traverse a bend from the azygos vein to the T9-T11 intercostal vein.
[Appendix 99]
60. The ablation catheter of paragraph 59, further comprising a guidewire lumen within said elongated shaft and having a distal port at a distal tip of said catheter.
[Appendix 100]
Each of the distal ablation electrode and the proximal ablation electrode can be an RF ablation electrode, a coiled wire electrode, a laser cut RF electrode, a conductive ink printed RF electrode, an RF electrode on an inflatable balloon (e.g. , conductive inks, flexible circuits), conductive membrane RF electrodes, RF electrodes on expandable cages or meshes, ultrasonic ablation transducers, electroporation electrodes, cryoablation elements, or virtual RF electrodes. 60. The ablation catheter of Clause 59, comprising:
[Appendix 101]
60. The ablation catheter of Clause 59, wherein the distal ablation electrode and the proximal ablation electrode are adapted and configured to deliver ablation energy circumferentially to create a circumferential lesion.
[Appendix 102]
1. An ablation catheter for transvascular ablation of the thoracic splanchnic nerve, in particular for ablating the greater splanchnic nerve or the greater splanchnic nerve root, comprising:
an elongated shaft having a length such that a distal section of the elongated shaft can be placed in a T9, T10, or T11 intercostal vein;
An electrically conductive flexible ablation element mounted on said elongated shaft distal section, connectable to an ablation energy source and having a length in the range of 5-25 mm (preferably 10-20 mm, optionally 15 mm). the electrically conductive flexible ablation element configured to create ablation) in the range of ~20 mm);
an ablation catheter including;
[Appendix 103]
103. The ablation catheter of paragraph 102, wherein said electrically conductive flexible ablation element has an axial length of 5-25 mm, preferably 10-25 mm, such as 15-20 mm.
[Appendix 104]
104. The ablation catheter of paragraph 102 or 103, wherein the distal section has a maximum outer diameter in the range of 1.5-3 mm, at least in the delivery state of the catheter.
[Appendix 105]
105. The ablation catheter of any one of clauses 102-104, wherein said elongated shaft has a length of 100-140 cm, optionally 110-130 cm.
[Appendix 106]
said conductive flexible ablation elements being a plurality of axially spaced apart each configured to create an ablation having a length in the range of 1-12 mm (optionally 2-12 mm); and/or each of said plurality of axially consecutive ablation elements forming said electrically conductive flexible ablation elements has a length of 1 to 12 mm (optionally 2 to 12 mm). 106. The ablation catheter of any one of clauses 102-105, wherein the ablation catheter is
[Appendix 107]
said electrically conductive flexible ablation elements are each configured to create elongated ablations ranging in length from 5 to 12 mm (optionally 6 to 11 mm, more optionally 7 to 10 mm) in an axial direction; and/or
each of said plurality of axially consecutive ablation elements forming said electrically conductive flexible ablation element has a length of 5-12 mm (optionally 6-11 mm, more optionally 7-10 mm);
107. The ablation catheter of any one of clauses 102-106.
[Appendix 108]
optionally, the length of each of the plurality of axially consecutive ablation elements forming the electrically conductive flexible ablation element is greater than the maximum outer diameter of the elongated shaft distal region in the delivery state of the catheter; 108. The ablation catheter of any one of clauses 102-107, wherein the ablation catheter is at least twice the maximum outer diameter at .
[Appendix 109]
The electrically conductive flexible ablation element comprises or is formed from a first ablation element and a second ablation element axially spaced from the first ablation element. 109. The ablation catheter of any one of clauses 102-108, wherein said first and second ablation elements are mounted on said shaft.
[Appendix 110]
An axial spacing exists between two successive ablation elements of each of said plurality of axially successive ablation elements, in particular between said first ablation element and said second ablation element. 109. The ablation catheter of any one of clauses 106-109, wherein there is an axial spacing at .
[Appendix 111]
110, wherein said axial spacing is 8 mm or less, optionally 5 mm or less, more optionally said axial spacing is 0.5-5 mm, even more optionally 1-4 mm; The described ablation catheter.
[Appendix 112]
Clause 106, wherein each ablation element of said electrically conductive flexible ablation elements has a coiled configuration, in particular said first ablation element has a coiled configuration and said second ablation element has a coiled configuration. 112. The ablation catheter of any one of clauses -111.
[Appendix 113]
The coiled configuration of each ablation element is the same in all respects as the coiled configuration of the other ablation elements of the electrically conductive flexible ablation element, and in particular the coiled configuration of the first ablation element is 113. The ablation catheter of paragraph 112, which is the same in all respects as the coiled configuration of the second ablation element.
[Appendix 114]
The coiled configuration of the first ablation element differs from the coiled configuration of the second ablation element in at least one manner selected from the following:
the length of the first ablation element is different than the second ablation element;
a coil orientation (e.g., left-handed or right-handed) of the first ablation element is different from that of the second ablation element;
the pitch of the first ablation element is different than the second ablation element;
A wire thickness of the first ablation element is different from that of the second ablation element.
the outer diameter of the distal region at the location of the first ablation element is different from the outer diameter of the distal region at the location of the second ablation element, or
the cross-sectional profile of the first ablation element is different than the cross-sectional profile of the second ablation element;
113. The ablation catheter of paragraph 112.
[Appendix 115]
Each ablation element of said electrically conductive flexible ablation elements comprises or is substantially made of a superelastic material such as nitinol, and in particular said first ablation element and said second ablation element comprise nitinol. 115. The ablation catheter of any one of clauses 106-114, comprising or made of a superelastic material such as.
[Appendix 116]
Each ablation element of the conductive flexible ablation elements has sufficient flexibility to allow the distal section to be advanced from the azygos vein into one of the T9, T10, or T11 intercostal veins. In particular, said first ablation element and said second ablation element are sufficiently flexible to allow said distal section to be advanced from the azygos vein into one of the T9, T10, or T11 intercostal veins. 115. The ablation catheter of any one of clauses 106-114, which is flexible.
[Appendix 117]
at least one of said ablation elements, in particular at least one of said first and second ablation elements, is made from a laser-cut tubular element (optionally a nitinol tube); and/or At least one of said ablation elements, in particular at least one of said first and second ablation elements, comprises a wire mesh or wire braid and/or at least one of said ablation elements, in particular said 117. The ablation catheter of any one of clauses 106-111 and 115-116, wherein at least one of the first and second ablation elements is a ring electrode having a length of 5 mm or less, optionally around 3 mm. .
[Appendix 118]
118. The ablation catheter of any one of clauses 106-117, wherein the diameter of each of said ablation elements, optionally both said first and second ablation elements, is expandable.
[Appendix 119]
The distal section is more flexible than the rest of the elongated shaft and is as small as 5 mm to flexibly traverse the bend from the azygos vein to the T9, T10, or T11 intercostal vein. 119. The ablation catheter of any one of clauses 102-118, configured to assume an angle of up to 120 degrees with a radius of curvature of .
[Appendix 120]
Clauses 102-119, wherein said electrically conductive flexible ablation element is configured to deliver ablation energy circumferentially and/or to deliver ablation energy radially symmetrically about said ablation element The ablation catheter according to any one of Claims 1 to 3.
[Appendix 121]
The electrically conductive flexible ablation element extends circumferentially through the tissue surrounding the intercostal vein for a range of 2-10 mm (optionally 121. The ablation catheter of any one of clauses 102-120, configured to ablate at a depth in the range of 2-8 mm, more optionally in the range of 3-8 mm.
[Appendix 122]
122. The ablation catheter of any one of Clauses 102-121, wherein the ablation catheter includes a proximal end, a distal end, and the distal section includes the most distal 7 cm of the ablation catheter.
[Appendix 123]
1. An ablation catheter for transvascular ablation of the thoracic splanchnic nerve, in particular for ablating the greater splanchnic nerve or the greater splanchnic nerve root, comprising:
an elongated shaft having a length such that a distal region of the elongated shaft can be placed in a T9, T10, or T11 intercostal vein;
at least one ablation element mounted on the elongated shaft distal region, the ablation element being connectable to an ablation energy source;
at least one irrigation port configured to act on the elongated shaft distal region and configured to be connectable to a flow source;
an ablation catheter including;
[Appendix 124]
comprising several irrigation ports, said irrigation ports being fluid/connectable to said fluid source, distributed along said distal region of said elongated shaft, in particular at least ten irrigation ports; 124. The ablation catheter of any one of clauses 1-123, uniformly distributed along the distal region of the elongated shaft.
[Appendix 125]
Clauses 1-including an irrigation lumen extending within said elongated shaft, said irrigation lumen connected to one or more irrigation ports and connectable to said fluid source at a proximal region of said elongated shaft 124. The ablation catheter according to any one of clauses 124 to 124.
[Appendix 126]
126. The ablation catheter of any one of clauses 123-125, wherein the one or more irrigation ports are located on a distal end region surface not covered by any ablation element.
[Appendix 127]
comprising a plurality of ablation elements, each of said plurality of ablation elements having a length of 1-12 mm, optionally 2-12 mm, more optionally 6-11 mm, even more optionally 6-10 mm; 126. The ablation catheter of any one of 123-126.
[Appendix 128]
128. The ablation catheter of any one of clauses 123-127, wherein the one or more irrigation ports are located in spaces between successive ablation elements or ablation element portions of the distal region.
[Appendix 129]
The ablation elements are axially spaced one ablation element relative to the other ablation element, and the axial spacing between the first ablation element and the second ablation element is 128. Any one of clauses 123-128, wherein the axial spacing is 8 mm or less, optionally 5 mm or less, more optionally, said axial spacing is 0.5-5 mm, even more optionally 1-4 mm. an ablation catheter as described above.
[Appendix 130]
Each ablation element has a coiled configuration, and in particular, the catheter includes a first ablation element having a coiled configuration and a second axially spaced ablation element having a coiled configuration. 130. The ablation catheter of any one of Clauses 123-129, comprising:
[Appendix 131]
131. Any one of clauses 123-130, wherein one or more irrigation ports are positioned between the distal and proximal ends of each ablation member, said irrigation ports being located between windings of each ablation member. an ablation catheter as described above.
[Appendix 132]
132. The ablation catheter of any one of Clauses 123-131, comprising a first irrigation port distal to any ablation element.
[Appendix 133]
The first irrigation port is distal to a distal ablation element, the ablation catheter further includes a proximal ablation element, and/or the ablation catheter further comprises a proximal ablation element distal to the proximal ablation element. 133. The ablation catheter of paragraph 132, comprising a second irrigation port at .
[Appendix 134]
134. The ablation catheter of any one of Clauses 123-133, comprising one or more irrigation ports between the windings of the coiled proximal ablation element.
[Appendix 135]
135. The ablation catheter of any one of Clauses 123-134, comprising one or more irrigation ports between turns of the coiled distal ablation element.
[Appendix 136]
a proximal radiopaque marker overlying the distal region and located proximal to all ablation elements; and 136. The ablation catheter of any one of Clauses 123-135, comprising a distal radiopaque marker located distal to all ablation elements.
[Appendix 137]
1. An ablation catheter for transvascular ablation of the thoracic splanchnic nerve, in particular for ablating the greater splanchnic nerve or the greater splanchnic nerve root, comprising:
an elongated shaft having a length such that a distal section of the elongated shaft can be placed in a T9, T10, or T11 intercostal vein;
at least one ablation element mounted on said elongated shaft distal section, said ablation element being connectable to an ablation energy source;
at least one radiopaque marker,
a proximal radiopaque marker overlying the distal region and located proximal to all ablation elements; and/or
A distal radiopaque marker located distal to all ablation elements
the at least one radiopaque marker comprising
Catheter containing.
[Appendix 138]
The proximal radiopaque marker is located immediately proximal to the ablation element or immediately to the proximal-most ablation element of the ablation elements mounted on the distal region of the catheter. 138. The catheter of paragraph 137, located proximally.
[Appendix 139]
The distal radiopaque marker is located immediately distal of the ablation element or immediately of the most distal of the ablation elements mounted on the distal region of the catheter. 139. The catheter of paragraph 137 or 138, located distally.
[Appendix 140]
If the proximal radiopaque marker is located at the venous ostium where the azygos vein meets the intercostal vein or is located at the midline of the spine of a human patient, then the ablation element is positioned within the intercostal vein. 139. according to any one of clauses 137 to 139, wherein the proximal radiopaque marker is configured and positioned relative to the ablation element to be located at a suitable ablation site in one of catheter.
[Appendix 141]
The distal radiopaque marker is at least 3 mm from the costovertebral joint. said distal radiopaque marker being configured such that said ablation element is positioned at a safe ablation site in one of said intercostal veins, preferably at a distance of at least 5 mm, said ablation element 141. The catheter of any one of clauses 137-140, positioned relative to.
[Appendix 142]
The ablation elements are electrically conductive formed of a first ablation element in a coiled configuration and a second ablation element in a coiled configuration axially spaced from the first ablation element. a flexible ablation element,
The axial spacing between said first ablation element and said second ablation element is no greater than 8 mm, optionally no greater than 5 mm, more optionally said axial spacing is between 0.1 and 5 mm. yes, and even more optionally between 0.5 and 1 mm;
said conductive flexible ablation element has a length of 5 to 25 mm, preferably 15 to 20 mm;
the proximal radiopaque marker is located immediately proximal to the first ablation electrode at a distance of 0.1 to 5 mm; and/or
a distal radiopaque marker is located immediately distal to the second ablation element at a distance of 0.1 to 5 mm;
142. The catheter of any one of clauses 137-141.
[Appendix 143]
143. The ablation catheter of any one of Clauses 102-142, further comprising a temperature sensor mounted on said elongated shaft distal region.
[Appendix 144]
144. The ablation catheter of paragraph 143, wherein the temperature sensor is positioned between a first ablation element and a second ablation element and mounted on the shaft.
[Appendix 145]
145. The ablation catheter of paragraph 143 or 144, further comprising one or more of a temperature sensor distal to the distal ablation element or a temperature sensor proximal to the proximal ablation element.
[Appendix 146]
The distal section is more flexible than the rest of the elongated shaft and is as small as 5 mm to flexibly traverse the bend from the azygos vein to the T9, T10, or T11 intercostal vein. 146. The ablation catheter of any one of clauses 102-145, wherein the ablation catheter is configured to assume an angle of up to 120 degrees with a radius of curvature of .
[Appendix 147]
Clauses 102-, including a handle at the proximal end of the catheter, the handle containing an electrical connection configured to enable connection between the electrically conductive flexible ablation element and the ablation energy source; 146. The ablation catheter according to any one of clauses 146 to 146.
[Appendix 148]
148. The ablation catheter of any one of Clauses 102-147, further comprising a guidewire lumen within said elongated shaft.
[Appendix 149]
1. A method of characterizing the location of a human patient's azygos vein relative to a portion of the spine of the patient, comprising:
At least a portion of the patient's spine and vasculature (particularly the azygos vein and/or one or more intercostal veins) using an imaging device (particularly a radiopaque contrast agent in the patient's vasculature). or
at least one radiopaque device positioned within said azygos vein and/or within one or more intercostal veins relative to a portion of said spine, optionally radiopaque for a guidewire imaging the radiopaque device, including a sexual portion, using an imaging device (particularly using a radiographic imaging device) to visualize the patient relative to the midline of the spine; characterizing the location of the azygos vein and determining whether the azygos vein is centered or left biased relative to the midline of the vertebra based on one or more images generated by the imaging device; The step of determining whether it is skewed to the right
method including.
[Appendix 150]
1. A method of determining the appropriate location in the vasculature of a human patient to insert a catheter (especially to allow ablation of a greater splanchnic nerve or greater splanchnic nerve root), comprising:
performing the method of Clause 149;
A transvascular ablation catheter (especially the determining where the ablation element of the catheter according to any one of the preceding paragraphs should be placed;
method including.
[Appendix 151]
The radiopaque marker is a proximal radiopaque marker located proximal to the ablation element, and the distal section further comprises a distal radiopaque marker located distal to the ablation element. 12. The method of Claim 1, comprising an impermeable marker.
[Appendix 152]
152. The method of paragraph 151, wherein said ablation element is 15-20 mm in length.
[Appendix 153]
153. The method of clause 151 or 152, wherein the ablation element comprises first and second axially spaced apart flexible ablation elements, optionally both of which have a coiled configuration. .
[Appendix 154]
The axial spacing between the first ablation element and the second ablation element is 0.1-1 mm, such as 0.5-1 mm, such as 0.6 mm, 0.65 mm, 0 154. The method of paragraph 153, which is 0.7 mm, 0.75 mm, 0.8 mm, or 0.85 mm.
[Appendix 155]
154. According to any one of clauses 151-154, wherein the distal radiopaque marker is 0-5 mm, optionally 0-3 mm, such as 0-2 mm distal to the distal end of the ablation element. the method of.
[Appendix 156]
156. According to any one of clauses 151-155, wherein the proximal radiopaque marker is 0-5 mm, optionally 0-3 mm, such as 0-2 mm proximal to the proximal end of the ablation element. the method of.
[Appendix 157]
The method does not include rotationally orienting the distal section, and the method further repositions the ablation element within the T9, T10, or T11 intercostal vein after beginning the step of delivering energy. 157. The method of any one of clauses 151-156, which does not include the step of re-delivering energy from the ablation element with the ablation element.
[Appendix 158]
158. The method of any one of clauses 151-157, further comprising moving the distal section to another one of the T9, T10, or T11 intercostal veins.
[Appendix 159]
159. The method of Clause 158, further comprising delivering energy from the ablation in the other one of the T9, T10, or T11 intercostal veins.
[Appendix 160]
The method does not include rotationally orienting the distal section in the other one of the T9, T10, or T11 intercostal veins, and the method further includes: repositioning the ablation element in the other one of the T9, T10, or T11 intercostal veins to deliver energy from the ablation element after initiation of the step of delivering energy in the other one of the T9, T10, or T11 intercostal veins; 159. The method of Supplementary Note 159, which does not comprise the step of re-delivering
[Appendix 161]
160. The method of any one of clauses 151-160, further comprising any step of any one of clauses 2-58.

Claims (14)

1. An ablation catheter for transvascular ablation of the thoracic splanchnic nerve, in particular for ablating the greater splanchnic nerve or the greater splanchnic nerve root, comprising:
an elongate shaft having a length that allows a distal section of the elongate shaft to be positioned within a T9, T10, or T11 intercostal vein;
an electrically conductive flexible ablation element mounted on the distal section of the elongated shaft;
the electrically conductive flexible ablation element is connectable to an ablation energy source;
said electrically conductive flexible ablation element comprising a plurality of axially spaced apart ablation elements;
said conductive flexible ablation element having an axial length of 10-25 mm;
each of the plurality of ablation elements forming the conductive flexible ablation element has a length of 5-12 mm;
The distal section is more flexible than the rest of the elongated shaft, having a small curvature of 5 mm for flexibly traversing bends from the azygos to the T9, T10, or T11 intercostal veins. It is configured to take an angle of up to 120 degrees with the radius,
said electrically conductive flexible ablation element configured to deliver ablation energy circumferentially and/or to deliver ablation energy radially symmetric about said ablation element;
each ablation element of the electrically conductive flexible ablation elements has a coiled configuration;
ablation catheter. The ablation catheter of Claim 1, wherein each of said ablation elements has an expandable diameter. Each of said plurality of axially consecutive ablation elements forming said electrically conductive flexible ablation element is greater than, and optionally at least said maximum outer diameter taken by said elongated shaft distal region in the delivery state of said catheter. having a length that is twice the outer diameter,
3. The ablation catheter of claims 1 or 2, wherein the elongated shaft distal region has a maximum outer diameter within the range of 1.5-3 mm, at least in the delivery state of the catheter. The electrically conductive flexible ablation element comprises or is formed from a first ablation element and a second ablation element axially spaced from the first ablation element. 4. The ablation catheter of any one of claims 1-3, wherein the first and second ablation elements are mounted on the shaft. An axial spacing exists between two successive ablation elements of each of said plurality of axially successive ablation elements, in particular between said first ablation element and said second ablation element. There is an axial spacing at
Claim 1, wherein the axial spacing is 8 mm or less, optionally 5 mm or less, more optionally the axial spacing is 0.5-5 mm, even more optionally 1-4 mm. 5. The ablation catheter according to any one of items 4 to 4. The coiled configuration of each ablation element is identical in all respects to the coiled configuration of the other ablation elements of the electrically conductive flexible ablation element, and in particular the coiled configuration of the first ablation element is 6. The ablation catheter of any one of claims 1-5, identical in all respects to the coiled configuration of the second ablation element. The coiled configuration of the first ablation element differs from the coiled configuration of the second ablation element in at least one manner selected from the following:
the length of the first ablation element is different than the second ablation element;
a coil orientation (e.g., left-handed or right-handed) of the first ablation element is different from that of the second ablation element;
the pitch of the first ablation element is different than the second ablation element;
A wire thickness of the first ablation element is different from that of the second ablation element.
the outer diameter of the distal region at the location of the first ablation element is different from the outer diameter of the distal region at the location of the second ablation element, or
the cross-sectional profile of the first ablation element is different than the cross-sectional profile of the second ablation element;
7. The ablation catheter of any one of claims 1-6. The electrically conductive flexible ablation element circumferentially penetrates the tissue surrounding the intercostal vein to a depth in the range of 2-10 mm when the catheter is positioned within the distal region within the intercostal vein. , optionally at a depth in the range 2-8 mm, more optionally at a depth in the range 3-8 mm. ablation catheter. 9. The ablation catheter of any one of claims 1-8, wherein the ablation catheter includes a proximal end, a distal end, and the distal section includes the most distal 7 cm of the ablation catheter. comprising several irrigation ports, said irrigation ports being connectable to a fluid source and distributed along said distal region of said elongate shaft, in particular at least ten irrigation ports being connected to said elongate shaft; 10. The ablation catheter of any one of claims 1-9, uniformly distributed along the distal region. 11. An irrigation lumen extending through said elongated shaft, said irrigation lumen connected to one or more irrigation ports and connectable to said fluid source at a proximal region of said elongated shaft. The ablation catheter described in . the one or more irrigation ports are located on a distal end region surface not covered by any ablation element; and/or
12. The ablation catheter of claim 10 or 11, wherein the one or more irrigation ports are located in spaces between successive ablation elements or ablation element portions of the distal region. 13. One or more irrigation ports are positioned between the distal and proximal ends of each ablation element, said irrigation ports being located between windings of each ablation element. The ablation catheter described in . a proximal radiopaque marker overlying the distal region and located proximal to all ablation elements; and /or a distal radiopaque marker located distal to all ablation elements, optionally wherein said at least one radiopaque marker is between 1 and 15 mm of said distal ablation element, or 0 14. The ablation catheter of any one of claims 10 to 13, which is in the range of .1-3 mm, optionally 0.5 mm, 1 mm or 1.5 mm.