The present invention relates to medical methods for treating obstructive and or inflammatory lung disease, and more specifically to minimally invasive medical methods and apparatus' for ablating the inner wall of the airways to limit contraction and obstruction within airways.
Chronic obstructive pulmonary disease (COPD) and asthma are lung inflammatory diseases and affect many people. Each disease is characterized by limited airflow, and interferes with normal breathing. Although COPD includes a number of diseases including chronic bronchitis and emphysema, it is generally characterized by airflow obstruction. People with airflow obstruction may have a number of symptoms including smooth muscle contraction, chronic cough with excess sputum production, and general thickening of the airway wall, all of which result in obstruction of normal breathing.
Various approaches to treat COPD and asthma include pharmacological treatment and interventional treatments.
Pharmacological treatment is an approach applied to most patients. For example, it is not uncommon for a physician to administer an inhaled bronchodilator (short or long acting) once or twice daily to relax and temporarily open airways. However, the side effects of the pharmacological agents include: nausea and vomiting, diarrhea, palpitations, a rapid heartbeat, an irregular heartbeat, headaches, and problems sleeping (insomnia), all of which are undesirable.
On the other hand, some patients are candidates for interventional treatments.
A variety of thermal ablation based interventional treatments have been described as therapies to treat diseased airways.
U.S. Pat. No. 9,867,648 to Mulcahey, for example, describes a cryospray treatment of airway tissue. Spray cryotherapy is applied by spraying liquid nitrogen directly onto the bronchial wall with the intent of ablating superficial airway cells and initiating a regenerative effect on the bronchial wall.
Radiofrequency ablation techniques have also been described wherein energy is delivered to the airway wall in a variety of locations to ablate diseased tissue. An example of a RF based bronchial thermoplasty to reduce excess smooth muscle in the airway is described in U.S. Pat. No. 6,488,673 to Laufer et al. See also, the The Alair™ Bronchial Thermoplasty System (manufactured by Boston Scientific, Corporation, Marlborough, Mass., USA).
These thermal ablative technologies non-selectively ablate various layers of the airway wall, often undesirably ablating non-target tissues beyond the epithelium. As a consequence of damage to tissues beyond the therapeutic targets of the epithelium, an inflammatory cascade can be triggered, resulting in inflammation, which can lead to an exacerbation, and remodeling. As a result, the airway lumen can be further reduced. Thus, continued improvements in interventional procedures are needed which are more controlled, targeted to specific depths and structures that match the physiologic malady, while limiting the amount of inflammatory response and remodeling.
Accordingly, a system and method to treat obstructive lung and inflammatory disease that overcomes the above-mentioned challenges is still desirable.
The present invention includes an apparatus, system and method for ablating tissue for the treatment of obstructive lung or inflammatory diseases, and is particularly suitable for treatment of chronic bronchitis and asthma.
In embodiments, vapor is aimed directly towards the surface of the airway to create a ring-shaped ablation layer extending into the airway wall to a depth. In embodiments, the depth is controlled by ablation parameters to include only the epithelial layers and exclude other layers, such as smooth muscle. In embodiments, the depth of the ablation layer is controlled to be less than 1 mm, and more preferably between 0.3 and 0.7 mm, and most preferably about 0.4 to 0.6 mm.
In embodiments, an apparatus includes a distal section and at least one egress port along the distal section. The egress port aims condensable vapor at the airway wall.
In embodiments, the egress port is aimed such that the flowpath of the vapor is substantially perpendicular to the airway wall.
The configuration of the egress port(s) may vary. In embodiments, the distal section has a tubular shaped wall, and the egress port is disposed along the wall.
In embodiments, a plurality of egress ports are disposed circumferentially about the wall of the catheter. Additional egress ports or sets of egress ports may be located along a length of the catheter shaft.
In embodiments, the target region or section of the airway is isolated from a non-target section of the airway by at least one occluding member. The occluding member may be disposed proximal or distal to the egress port. In embodiments, occluding members are present on both the distal and proximal side of the egress port to define a volume or space which the vapor fills. In embodiments, the occluding members are expandable members such as an inflatable balloon.
In embodiments, the shaft may be operable with a proximal hub or handle to rotate or axially move the distal working section and egress port(s) relative to the isolation member. The hub may include a means to controllably advance and rotate the shaft carrying the egress ports relative to the balloon. In an embodiment, the means is a threaded shaft and mating grooves to allow incremental advancement of one of the components to the other.
In embodiments, a target region along the airway, and optionally an optimal route to the target region, is predetermined.
In embodiments, the vapor is delivered in pulses, and optionally, the heated vapor and a cooling gas is delivered in pulses according to an adjustable or varying duty cycle.
In embodiments, the duty cycle is adjusted based on the measured depth of the lesion.
In embodiments, the duty cycle commences at a first range, and is adjusted to a second range wherein the second range is less than the first range. In embodiments, the first range is from 70 to 100%, and the second range is under 50%.
In embodiments, the method further comprises visually monitoring the surface of the airway and computing a real-time hue change as the ablation layer is forming. In embodiments, the depth of ablation is controlled by halting the vapor delivery if the real-time hue change reaches a predetermined threshold hue change.
Still other descriptions, objects and advantages of the present invention will become apparent from the detailed description to follow, together with the accompanying drawings.
Before the present invention is described in detail, it is to be understood that this invention is not limited to particular variations set forth herein as various changes or modifications may be made to the invention described and equivalents may be substituted without departing from the spirit and scope of the invention. As will be apparent to those of skill in the art upon reading this disclosure, each of the individual embodiments described and illustrated herein has discrete components and features which may be readily separated from or combined with the features of any of the other several embodiments without departing from the scope or spirit of the present invention. In addition, many modifications may be made to adapt a particular situation, material, composition of matter, process, process act(s) or step(s) to the objective(s), spirit or scope of the present invention. All such modifications are intended to be within the scope of the claims made herein.
Methods recited herein may be carried out in any order of the recited events which is logically possible, as well as the recited order of events. Furthermore, where a range of values is provided, it is understood that every intervening value, between the upper and lower limit of that range and any other stated or intervening value in that stated range is encompassed within the invention. Also, it is contemplated that any optional feature of the inventive variations described may be set forth and claimed independently, or in combination with any one or more of the features described herein.
All existing subject matter mentioned herein (e.g., publications, patents, patent applications and hardware) is incorporated by reference herein in its entirety except insofar as the subject matter may conflict with that of the present invention (in which case what is present herein shall prevail).
Reference to a singular item, includes the possibility that there are plural of the same items present. More specifically, as used herein and in the appended claims, the singular forms “a,” “an,” “said” and “the” include plural referents unless the context clearly dictates otherwise. It is further noted that the claims may be drafted to exclude any optional element. As such, this statement is intended to serve as antecedent basis for use of such exclusive terminology as “solely,” “only” and the like in connection with the recitation of claim elements, or use of a “negative” limitation.
Now, with reference to
The respiratory system 10 may be characterized by a tree-like structure formed of branched airways including the trachea 18; left and right main stem bronchus 20 and 22 (primary, or first generation) and lobar bronchial branches 24, 26, 28, 30, and 32 (second generation). Segmental and subsegmental branches further bifurcate off the lobar bronchial branches (third and fourth generation). Each bronchial branch and sub-branch communicates with a different portion of a lung lobe, either the entire lung lobe or a portion thereof.
With reference to
Depending on the degree of the disease, the contracted and obstructed airways make breathing strained, if not impossible. Embodiments of the invention discussed herein provide methods and apparatus' to treat obstructive and/or inflammatory diseases of the lung.
Bronchoscopy Approach
Energy Generator
In embodiments, vapor generator 300 is configured as a self-contained, medical-grade generator unit comprising at least a vaporizing unit 302, a fluid inlet 304, and a vapor outlet 306. The vaporizing unit 302 comprises a fluid chamber for containing a fluid 301, preferably a biocompatible, sterile fluid, in a liquid state. In embodiments, vapor outlet 306 is coupled to one or more pipes or tubes 314, which in turn are placed in fluid communication with an energy delivery catheter 200. Vapor flow from vapor generator 300 to a catheter (and specifically a vapor lumen of said catheter) is depicted as a vapor flow circuit 314 wherein flow of the vapor in circuit 314 is indicated by arrows 314 in
Vaporizer unit 302 is configured to heat and vaporize a liquid contained therein. Other components can be incorporated into the biocompatible liquid 301 or mixed into the vapor. For example, these components can be used to control perioperative and/or post procedural pain, enhance tissue fibrosis, and/or control infection. Other constituents, for the purpose of regulating vapor temperatures and thus control extent and speed of tissue heating, can be incorporated; for example, in one implementation, carbon dioxide, helium, other noble gases can be mixed with the vapor to decrease vapor temperatures.
Vaporizing unit 302 is also shown having a fluid inlet 304 to allow liquid 301 to be added to the fluid chamber as needed. Fluid chamber can be configured to accommodate or vaporize sufficient liquid as needed to apply vapor to one or more target tissues. Liquid in vaporizing unit 302 is heated and vaporized and the vapor flows into vapor outlet 306. A number of hollow tubular shafts or pipes 314 are adapted to fluidly connect vapor outlet 306 to the catheter, described herein.
With reference to
In embodiments, a catheter and vapor generator are configured to be directly coupled to one another via mating connectors. Vapor delivery is controlled by the generator, a controller external to the generator, or actuating buttons and mechanisms on the catheter itself. For example, the catheter may comprise a handpiece portion to control vapor doses.
Although the vapor generator is described above having various specific features, the components and configurations of the vapor generator and catheter systems may vary. Additional vapor ablation systems are described in, for example, U.S. Patent Publication No. 2015/0094607 to Barry et al., and U.S. Pat. Nos. 7,913,698 to Barry et al., and 8,322,335 to Barry et al., and 7,993,323 to Barry et al.
In other embodiments, a condensable vapor is created in the handle portion of the catheter system. Consequently, a separate vapor generator unit is not required. Systems including a resistive heater are described in, for example, U.S. Patent Publication No. 2016/0220297 to Kroon et al., U.S. Patent Publication No. 2014/0276713 to Hoey et al., and U.S. patent application Ser. No. 16/203,541, filed Nov. 28, 2018, and entitled “VAPOR ABLATION HANDPIECE”. Indeed, embodiments of the invention include a wide range of mechanisms to create and transport vapor through the working catheter as described herein.
Vapor Ablation Catheter
Vapor 470 is shown being emitted from an axially-aimed distal port 480 towards the target section of the airway. The catheter 440 also includes an isolation member 482 to isolate the vapor 470 to the target tissue. The isolation member is visually transparent, allowing the physician to see through the member. Examples of isolation members include, without limitation, inflatable members, balloons, and expandable members.
An isolation member 520 holds the catheter in place while emitting vapor and isolates the vapor to the target region. Additionally, in embodiments, the isolation member 520 includes a coupler 524, allowing the shaft 526 of the catheter to rotate relative to the isolation member. An example of a coupling mechanism is a tubular passageway through which the shaft 526 of the vapor catheter extends therethrough. Preferably, the components cooperate with one another to be fluidly sealed but axially and rotatably movable. In embodiments, an O-ring or gasket (e.g., a Teflon O-ring) is provided to facilitate a seal and permit motion between the components.
With reference to
Rotation may be clock-wise or counter clockwise. Example rotation angles are between 0 and 180, up to 360 or more. Additionally, the physician may axially advance the catheter in combination with rotation to generate an elongated tubular ablation zone along the surface of the airway.
The incremental or controlled movement may be accomplished via a shaft advancement means. In embodiments, the hub assembly 560 includes a threaded shaft 584 to allow for incrementally advancing and rotating of the shaft relative to the balloon. As a result of this motion, the catheter can create a circumferentially complete band ranging from 5 to 20 mm in width (w).
Depth (d)
The depth (d) of the ablation lesion may also be controlled. In embodiments, the physician controls ablation parameters for the vapor delivery to limit the depth (d) of ablation to less than 1 mm, and in embodiments, between 0.3 and 0.7 mm, and preferably less than 0.5 mm into the wall. In embodiments, the parameters include but are not limited to vapor temperature, flowrate, and duration of vapor delivery. Non-limiting exemplary time durations to limit the ablation depth (d) to the above desired depths is less than 1 minute, less than 30 seconds, and less than 10 seconds. Exemplary non-limiting temperatures range from that described above to more preferably less than 100 degrees C. In embodiments, the duration of vapor delivery and temperature are adjusted to ablate the upper layer of the epithelium including the goblet cells, or top layer of the epithelium, and to let the underling tissue architecture remain intact. In embodiments, the time and temperature are set as described above to treat only the epithelium cell layers discussed above yet not damage deeper layers.
The depth of thermal ablation can also be controlled by a pulsing or duty cycle application of the vapor. Pulsing allows for the limited vapor dispersed to condense and be followed by a brief cooling period which will slow penetration of the steam energy. Alternating steam and cooling gas application to the wall can provide a fine/precise depth of penetration. A 10% duty cycle (10 parts steam followed by 90 parts cooling) will result in a shallower penetration of the ablation than a 50% duty cycle. A controlled solenoid and valve mechanism (similar to a fuel injector) could be programed to alternate gasses and achieve this duty cycle. Where a slow and more precise ablation is desired (e.g., to ablate a target region but avoid the gastric nerve), the physician may opt for a lower duty cycle under 50%, or perhaps from 10 to 20%. On the other hand, where there are no obstacles to avoid in the ablation zone, the physician may opt for a higher duty cycle. In embodiments, the higher or fast ablation duty cycle may range from 70 to 100%.
The depth of penetration can be monitored via observation and color change of the bronchial wall via an optical comparator system. Without intending to being bound by theory, as vapor is applied to the bronchial surfaces, the pink coloration of the lumen will change from pink to white in a progressive fashion from all pink to all white, where partial ablation is a mix of pink and white coloration. With this color change a correlation can be established between the coloration and the depth of penetration. As all airways are not the exact hue of pink, one could similarly monitor the change from the original color to be correlated to the energy delivered and depth of penetration.
The measure (or computation) of color change could be performed by an optical comparator system capable of graphic processing of the color vs a known color scale. An example of a suitable optical assessment technology is BLD Blood Leak Detector, manufactured by Sonotec US Inc. (Islandia, N.Y.) or the TT Electronics Photologic V OPB9000 reflective optical sensor, manufactured by TT Electronics (Boston, Mass.). With such an optical quality assessment of hue and difference from baseline, a system and method could be controlled by a feedback loop which would stop the application of vapor when the color change desired (e.g., a threshold hue change) had been verified, therefore achieving the desired depth of penetration. In embodiments, the vapor emission is halted when the real-time color change of the surface of the airway reaches a predetermined threshold color change.
The duty cycle for vapor ablation may also be adjusted (or varied) during a procedure. A high duty cycle could be applied to start to speed initial growth of the ablation depth. With significant Hue change as assessed by the optical comparator system, the duty cycle could be reduced (e.g., reduced by 10-25, 50 or in some embodiments 75%) to slow the growth of the depth of penetration and arrive asymptotic to the desired depth of penetration/hue for a precise control.
Vapor 692 is shown aimed at the airway wall 620 and is limited to the volume defined between the isolation members 682, 684 and the airway wall 620. In this manner, collateral damage to non-target tissues and airways is prohibited.
The ports 910, 912, etc. are shown in a group. Adjacent ports are spaced from one another such that the vapor flowpath (as the vapor flows into the wall) from one port overlaps with the vapor flowpath from an adjacent port. In embodiments, the distance (center to center) between the adjacent ports ranges from 0.5 to 5 mm.
The number of egress ports 910, 912, etc. may vary widely and range from 1-20, and more preferably 6-12. Additionally, the shape and size of the egress ports may vary. In embodiments, the egress port has a circular shape and a diameter in the range of 0.1 to 2 mm.
Optionally, although not shown, an isolation member may be disposed proximally, distally, or both proximally and distally to the group of egress ports.
Also, the number of discrete groups of ports may vary from that shown in
Additional examples of vapor delivery catheter configurations are described in the literature. Another example of a vapor catheter having components and structures which may be combined with the subject invention is described in U.S. Pat. No. 8,444,636 to Shadduck and Hoey; and U.S. Patent Publication No. 2014/0025057 to Hoey and Shadduck. The catheter and tip configuration may vary widely and the invention is only intended to be limited as recited in the appended claims.
Chronic Bronchitis or Asthma Treatment Method
Step 1010 states to identify the target region along an airway in the lung of a patient to ablate. An example of a candidate region to ablate may be a portion along the trachea, main bronchus, bronchioles from 1 generation up to the 5 generation. Endoscopy or noninvasive means such as MRI may be applied to view and identify the target.
Step 1020 states to plan route to the target tissue. Optionally, planning software is employed to visualize the target region in renderings of the patient's lungs (e.g., a 3D reconstruction of the airway tree based on a patient's CT or MRI image data). Examples of route planning techniques are described in U.S. Pat. No. 9,037,215 and U.S. Patent Publication No. 2009/0156895, both to Higgins et al. See also the LungPoint® Planner, manufactured by Broncus Medical, Inc., (San Jose, Calif.).
Step 1030 states to advance the catheter to the target tissue. As described above, the physician may advance the catheter through the working channel of a scope to the target region.
Step 1040 states to isolate the target region. In embodiments, this step is performed as described above by inflating or expanding one or more isolation members to limit the vapor to the target region or section of airway.
Step 1050 states to aim an egress port of the catheter at the surface of the airway wall. Aiming may be performed as described above by rotation of the port, movement of the port axially, or providing multiple ports circumferentially or axially along the shaft of the catheter.
Optionally, the distance between the airway wall and the port is adjusted by, e.g., switching out another catheter having a different diameter shaft to position each of the egress ports closer or farther from the airway wall.
In embodiments, a method further comprises controlling or adjusting the distance from the egress port to the surface of the airway based on a target depth to be achieved by the emitted vapor.
Step 1060 states to deliver a vapor dose towards the target. As described herein, the vapor dose is controlled by various ablation parameters to provide an amount of energy to the target region to cause necrosis to a depth as described herein, and in particular embodiments, such that only the top layer of the epithelium is ablated. In embodiments, the ablation parameters are controlled such that the vapor dose ranges from 100 to 1000 calories. The amount of energy can be controlled by time duration, flow rate, temperature, duty cycle, and vapor quality.
The invention has been discussed in terms of certain embodiments. One of skill in the art, however, will recognize that various modifications may be made without departing from the scope of the invention. For example, numerous variations, changes, and substitutions will now occur to those skilled in the art without departing from the invention. For example, in embodiments, lesions may be created by the vapor systems described above which form non-band shaped lesions on the airway. Lesions may be sprayed/painted on epithelium of the airway in a non-contiguous manner, in patches, segments, half rings, arcuate segments, etc., and the control parameters can be used to limit the depth of the lesion to the target depth, preferably less than 1 mm so as to leave the underlying tissue architecture intact. Moreover, while certain features may be shown or discussed in relation to a particular embodiment, such individual features may be used on the various other embodiments of the invention.
This application is a continuation application of application Ser. No. 19/789,097, filed Feb. 12, 2020, and claims priority to provisional application No. 62/807,014, filed Feb. 18, 2019, the entirety of which is herein incorporated by reference for all purposes.
Number | Date | Country | |
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62807014 | Feb 2019 | US |
Number | Date | Country | |
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Parent | 16789097 | Feb 2020 | US |
Child | 18309476 | US |