Method for non-invasive lung treatment

Abstract

The invention provides an at least partially non-invasive method for treatment of a non-tumorous lung, often for treatment of chronic obstructive pulmonary disease or the lung. In a first aspect, a method for treatment of a non lung of a patient comprises directing radiation from outside the patient toward one or more target treatment regions of the lung so as to inhibit the chronic obstructive pulmonary disease.

Description

STATEMENT AS TO RIGHTS TO INVENTIONS MADE UNDER FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

Not Applicable

REFERENCE TO A “SEQUENCE LISTING,” A TABLE, OR A COMPUTER PROGRAM LISTING APPENDIX SUBMITTED ON A COMPACT DISK

Not Applicable

BACKGROUND OF THE INVENTION

The present invention is generally related to treatment of the lungs, and in one embodiment provides an at least in part non-invasive treatment of chronic obstructive pulmonary disease (COPD), including emphysema.

COPD is a major cause of morbidity and mortality in the United States and other industrialized countries. COPD may be characterized by airflow obstruction due to chronic bronchitis or emphysema. The airflow obstruction in COPD may be related to structural abnormalities in the smaller airways. Causes may include inflammation, fibrosis, goblet cell metaplasia, and smooth muscle hypertrophy in terminal bronchioles.

The incidence, prevalence, mortality, and health-related costs of COPD may be on the rise. COPD can affect the patient's whole life, often having three main symptoms: cough; breathlessness; and wheeze. At first, breathlessness may be noticed when running for a bus, digging in the garden, or walking uphill. Later, it may be noticed when simply walking in the kitchen. Over time, it may occur with less and less effort until it is present all of the time. COPD is a progressive disease and may have no cure. Current treatments for COPD include the prevention of further respiratory damage, pharmacotherapy, and surgery.

The prevention of further respiratory damage entails the adoption of a healthy lifestyle. Smoking cessation may be the single most important therapeutic intervention. However, regular exercise and weight control may also be important. Patients whose symptoms restrict their daily activities or who otherwise have an impaired quality of life may require a pulmonary rehabilitation program including ventilatory muscle training and breathing retraining. Long-term oxygen therapy may also become necessary.

Pharmacotherapy may include bronchodilator therapy to open up the airways as much as possible or inhaled beta-agonists. For those patients who respond poorly to the foregoing or who have persistent symptoms, ipratropium bromide may be indicated. Further, courses of steroids, such as corticosteroids, may be required. Lastly, antibiotics may be required to prevent infections and influenza and pneumococcal vaccines may be routinely administered. Unfortunately, early, regular use of pharmacotherapy may not alter the progression of COPD.

It has been postulated that the tethering force that tends to keep the intrathoracic airways open may be lost in emphysema. Hence, by surgically removing the most affected parts of the lungs, the force might be partially restored. Lung volume reduction surgery (LVRS) has at times been deemed promising, but has fallen out of favor. Although the benefits of the procedure are not universally recognized, patients may benefit from the LVRS in terms of an increase in forced expiratory volume, a decrease in total lung capacity, and a significant improvement in lung function, dyspnea, and quality of life. Improvements in pulmonary function after LVRS may be attributed to at least four possible mechanisms. These include enhanced elastic recoil, correction of ventilation/perfusion mismatch, improved efficiency of respiratory musculature, and improved right ventricular filling.

Lung transplantation is also an option for treatment of COPD. Unfortunately, this is appropriate for only those with advanced COPD. Given the limited availability of donor organs, lung transplant is far from being available to all patients.

There is a need for additional non-surgical options for permanently treating COPD without surgery. Recently proposed therapies includes non-surgical apparatus and procedures for lung volume reduction by permanently obstructing the air passageway that communicates with the portion of the lung to be collapsed. The therapy includes placing an obstruction in the air passageway that prevents inhaled air from flowing into the portion of the lung to be collapsed. Such lung volume reduction with concomitant improved pulmonary function may be obtained without the need for massively invasive surgery, but will generally involve introducing one or more devices into the lungs. Such devices may cause undesirable tissue responses, and may move or break due to physiological or fluid movement within the lungs, deterioration, or the like. Moreover, the diseased tissue beyond the obstruction will remain untreated, and the long term effects of this untreated, diseased tissue on adjacent healthy tissues, and on disease progression, may not be known.

In view of the foregoing, there is a need in the art for a new and improved apparatus and method for treatment of emphysema and/or chronic obstructive pulmonary disease. Such an improved treatment should be less invasive, preferably allowing treatments without surgery, and ideally allowing non-invasive treatments of the lungs from outside the body.

BRIEF SUMMARY OF THE INVENTION

The present invention provides non-invasive methods for treatment of the lungs, often for treatment of emphysema and/or chronic obstructive pulmonary disease.

In a first aspect, the invention provides a method for treatment of a lung of a patient. The method comprises directing radiation from outside the patient toward one or more target treatment regions of the lung so as to inhibit chronic obstructive pulmonary disease.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a radiation treatment system.

FIG. 2 is a schematic illustration of a simplified Maze lesion pattern.

FIG. 3A-3D illustrate alternative patterns of lesions in the heart for treatment of arrhythmia.

FIG. 4 illustrates stereotactic radiosurgery using the system of FIG. 1.

FIG. 5 is a flowchart schematically illustrating a radiosurgery treatment method.

FIG. 6 schematically illustrates a non-tumor treatment of a lung so as to inhibit chronic obstructive pulmonary disease.

DETAILED DESCRIPTION OF THE INVENTION

Radiosurgery is a known method of treating tumors in the body. The radiation can be delivered invasively in conjunction with traditional scalpel surgery, or through a percutaneous catheter. Radiation can also be delivered non-invasively from outside the body, through overlying tissue. Advances in stereotactic surgery have provided increased accuracy in registering the position of tissue targeted for treatment and a radiation source. For example, see U.S. Pat. Nos. 6,351,662 and 6,402,762. Stereotactic radiosurgery systems may be commercially available from ACCURAY, INC. of Sunnyvale, Calif., and BRAFNLAB. The Accuray Cyberknife™ stereotactic radiosurgery system has reportedly been used to provide targeted, painless, and fast treatment of tumors.

In one embodiment of the invention, stereotactic radiosurgery systems similar to those commercially available from Accuray and other manufacturers may be used to non-invasively treat the diseased lobe or lobes, bronchi, or other target regions and/or structures of a lung from outside the body. The diseased lung target regions will often be non-tumorous, and will often have damage associated with chronic obstructive pulmonary disease. By directing radiation beams to the diseased area and ablating the diseased tissue to render the area non-functional, such a non-invasive radiation treatment may create increased efficiency in other, non diseased lung segments. Such treatments may be applied for patients having emphysema or other disease states of the lung. Alternative energy sources other than radiation might also be employed in a similar non-invasive manner.

The following description will describe systems, methods, and devices suitable for treatment of disease states of the lung. These descriptions will often reference applications of the invention for treatment of tumors and/or the heart. Hence, these descriptions are for clarity of understanding of the capabilities of the systems, methods, and devices of the present invention, and the invention is not limited thereby.

An exemplary Cyberknife™ stereotactic radiosurgery system 10 is illustrated in FIG. 1. Radiosurgery system 10 has a single source of radiation, which moves about relative to a patient. Radiosurgery system 10 includes a lightweight linear accelerator 12 mounted to a highly maneuverable robotic arm 14. An image guidance system 16 uses image registration techniques to determine the treatment site coordinates with respect to linear accelerator 12, and transmits the target coordinates to robot arm 14 which then directs a radiation beam to the treatment site. When the target moves, system 10 detects the change and corrects the beam pointing in near real-time. Near real-time image guidance may avoid any need for skeletal fixation to rigidly immobilize the target.

Improvements in imaging and computer technology have led to advances in radiation treatment, often for targeting tumors of the spine and brain. The introduction of CT scanners enables surgeons and radiation oncologist to better define the location and shape of a tumor. Further improvements in imaging technology include MRI and PET scanners. In addition, radiation therapy has also been aided by enhancements in ancillary technologies such as simulators to help position patients and advanced computers to improve treatment planning to enable the radiation oncologist to deliver radiation from a number of different angles. Computer technology has been introduced that enable radiation oncologists to link CT scanners to radiation therapy, making treatment more precise and treatment planning faster and more accurate, thereby making more complex plans available. Such advancements allow integrated conformal therapy, in which the radiation beam conforms to an actual shape of a tumor to minimize collateral damage to the surrounding healthy tissue. By combining simulators and imaging and treatment planning computers, the irradiation can be precisely administered.

System 10 makes use of robot arm 14 and linear accelerator 12 under computer control. Image guidance system 16 can monitor patient movement and automatically adjust system 10 to maintain radiation registration with the selected target tissue. Rather than make use of radiosurgery system 10 and related externally applied radiosurgical techniques to tumors of the spine and brain tissues, the invention applies system 10 to numerous cardiac conditions, and in one exemplary method to the treatment of Atrial Fibrillation and/or a lung.

Tradition radiosurgery instruments without image guidance technology rely on stereotactic metal frames screwed into the patient's skull to accurately target a tumor. Traditional radiosurgery has its drawbacks, the biggest of which relate to the use of the frame, including the pain and difficulty of accurately reattaching the frame in precisely the same location, along with the inability to target tissues other than those in the neck and head. Conventional linear accelerators for these systems can also be the size and weight of an automobile. Frame-based radiosurgery is generally limited to isocentric or spherical target treatments. To allow a device which can precisely pinpoint and treat tissues throughout the body, system 10 makes use of a portable linear accelerator, such as those originally designed for industrial inspections, which can be carried on a person's back. Linear accelerators may be commercially available from SCHONBERG RESEARCH GROUP, SIEMENS, PICKER INTERNATIONAL INC. or VARIAN.

System 10 allows intensity modulated radiation therapy. Using computerized planning and delivery, intensity modulated radiation therapy conforms the radiation to the shape of (for example) a tumor. By using computers to analyze the treatment planning options, multiple beams of radiation match the shape of the tumor. To allow radiosurgery, system 10 can apply intense doses of high-energy radiation to destroy tissue in a single treatment. Radiosurgery with system 10 uses precise spatial localization and large numbers of cross-fired radiation beams. Because of the high dosage of radiation being administered, such radiosurgery is generally more precise than other radiation treatments, with targeting accuracies of 1 to 2 mm.

Linear accelerator 12 is robotically controlled and delivers pin-point radiation to target regions throughout the body of the patient. Radiation may be administered by using a portable linear accelerator such as that illustrated in FIG. 1. Larger linear accelerators may also generate the radiation in some embodiments. Such linear accelerators may be mounted on a large rotating arm that travels around the patient, delivering radiation in constant arcs. This process delivers radiation to the target tissue and also irradiates a certain amount of surrounding tissue. As a result, such radiation therapy may be administered in a series of relatively small doses given daily over a period of several weeks, a process referred to as fractionation. Each radiation dose can create some collateral damage to the healthy surrounding tissue.

In the exemplary embodiment, robot arm 14 of system 10 is part of a pure robotics system, providing six degree of freedom range of motion. In use, the surgeon basically pushes a button and the non-invasive procedure is performed automatically with the image guidance system continuously checking and re-checking the position of the target tissue and the precision with which linear accelerator 12 is firing radiation at the tumor. Image guidance system 16 provides x-ray image guidance that gives the surgeon the position of internal organs and skeletal anatomy. Image guidance system 16 continuously checks, during a procedure, that the target is at the same place at the end of the treatment that it was at the beginning. The exemplary image guidance system included with the Accuray CyberKnife™ radiosurgery system takes the surgeon's hand out of the loop. The surgeon may not even be in the operating room with the patient. Instead, the image guidance system guides the procedure automatically on a real-time basis. By combining advanced image guidance and robotics, system 10 has proven effective in treating head and neck tumors without having to resort to stereotactic metal frame screwed into the skull of a patient.

Image guidance system 16 includes diagnostic x-ray sources 18 and image detectors 20, this imaging hardware comprising two fixed diagnostics fluoroscopes. These fluoroscopes provide a stationary frame of reference for locating the patient's anatomy, which, in turn, has a known relationship to the reference frame of robot arm 14 and linear accelerator 12. System 10 can determine the location of the skull or spine in the frame of reference of the radiation delivery system by comparing digitally reconstructed radiographs derived from the treatment planning images with radiographs acquired by the real-time imaging systems of the fluoroscopes.

Once the skeletal position is determined, the coordinates are relayed to robot arm 14, which adjusts the pointing of linear accelerator 12 and radiation is delivered. The speed of the imaging process allows the system to detect and adjust to changes in target position in less than one second. The linear accelerator is then moved to a new position and the process is repeated. Alternative systems may make use of laser triangulation, which refers to a method of using so-called laser tattoos to mark external points on the skin's surface so as to target the location of internal organs and critical structures. An alternative system commercialized by BRAINLAB uses a slightly different approach that measures chest wall movements.

The exemplary CyberKnife™ radiosurgery system is currently available for treatment of lesions throughout the cervical spine. These lesions may be benign or malignant, such as metastasis, meningiomas, and arterial venous malformations, the CyberKnife™ radiosurgery system has been used to successfully treat metastic lesions in patients who are otherwise not candidates for surgery or lesions which are not amenable to open techniques. Progress has also been reported in developing the CyberKnife™ radiosurgery system for use in the thoracic and lumbar regions as well, with preliminary experience being indicated as promising. System 10 combines robotics and advanced image-guidance to deliver true frameless radiosurgery. Multiple beams of image guided radiation are delivered by robot arm 14 mounted linear accelerator 12. The radiation can converge upon a tumor, destroying it while minimizing exposure to surrounding healthy tissue. Elimination of a stereotactic frame through the use of image guided robotics enables system 10 to treat targets located throughout the body, not just in the head. Radiosurgery is thus possible in areas such as the spine that have traditionally been difficult to treat in the past with radiosurgery, and for pediatric patients such as infants, whose skulls are too thin and fragile to undergo frame-based treatment.

System 10 allows ablation anywhere in the patient's body. The image-guidance system tracks bony landmarks of the skull to target radiation accurately. For body treatments, the image-guidance tracks small markers or fiducials percutaneously implanted in the tumor to target radiation. Advantages of system 10 include a treatment which can be provided on an outpatient basis, providing a painless option without the risk of complications associated with open surgery. Treatment may be applied in a single-fraction or hypo-fractionated radiosurgery (usually 2 to 5 fractions) for treatment near sensitive structures. System 10 provides flexibility in approach through computer control of flexible robotic arm 14 for access to hard-to-reach locations. System 10 also allows isocentric (for spherical) or non-isocentric (for irregularly shaped) treatments. Through the use of robotic arm 14, harm to the critical structures surrounding a lesion may be reduced. After careful planning, the precise robotic arm can stretch to hard-to-reach areas. The precise radiation delivered from the arm then minimizes the chance of injury to critical surrounding structures, with near-real-time image-guidance system 16 eliminating the need for rigid immobilization, allowing robot arm 12 to track the body throughout the treatment.

Referring now to FIG. 2, Cox and his colleagues first described the Maze procedure for treatment of atrial fibrillation. In the original Maze procedure, ectopic re-entry pathways of the atria are interrupted by introducing scar tissue using a scalpel. In FIG. 2, a simple Maze path is conceptually illustrated. Maze lesion pattern 30 has one entrance 32, one exit 34, and one through path 36 with multiple blind alleys 38. Since the initial description of the Maze procedure by Cox and colleagues, a number of related open surgical approaches have been devised for the treatment of atrial fibrillation. Although successful in the irradication of atrial fibrillation in a high percentage of cases, these procedures are invasive, requiring median sternotomy, cardiopulmonary bypass, cardioplegic arrest, extensive cardiac dissection, and/or multiple atrial incisions. These procedures are also associated with significant morbidity. There are a number of iterations of the Cox procedure, including the Cox-Maze III procedure. While this operation has proven to be effective, it has significant shortcomings. The performance of the Cox-Maze III procedure requires cardiopulmonary bypass and an arrested heart. In most hands, it adds significantly to the cross-clamp time. Because of its perceived difficulty, few surgeons have learned to perform this operation. Finally, there is significant morbidity, particularly in terms of pacemaker requirements. These problems have led researchers to evaluate strategies to simplify the surgical treatment of atrial fibrillation.

It has been suggested that in many patients, atrial fibrillation may be caused by re-entry wavelets limited to specific areas near the origins of the pulmonary veins. Success has also been reported with more limited procedures aimed at electrical isolation with discreet atrial lesions, utilizing atriotomy, radiofrequency ablation, or cryoablation. As can be understood with reference to FIGS. 3A through 3D, alternative approaches have involved both investigating different lesion sets and using a variety of energy sources to create linear lesions of ablation to replace the more time-consuming surgical incisions. These newer procedures have the potential to decrease the procedure time by eliminating the extensive sewing associated with the many atrial incisions of the traditional Cox-Maze III procedure. A number of different technologies have been adopted to achieve this strategy. These include cryoablation, unipolar and bipolar RF energy, microwave energy, laser energy, and ultrasound. In general, the goals of atrial fibrillation ablation are to cure atrial fibrillation by creating linear lines of conduction block in the atria to replace the surgical incisions. These principally apply endocardial ablation in the beating heart, with most devices involving heating the tissue to cause coagulation necrosis.

Catheter-based atrial fibrillation ablation allows a less invasive approach, shortens operative time, and simplifies the operation. This reduces morbidity and mortality of the atrial fibrillation surgery, allowing for a more widespread application of these procedures. These operations decrease the invasiveness of the Cox-Maze III procedure, but in evaluating failures, it is often difficult to differentiate whether the lesion set was inadequate, or whether the technology was unable to create transmural lesions. Lesion patterns that have been studied in animal models include the original Maze III, the radial incisions approach, the tri-ring lesion pattern, and the Star procedure. Alternative patterns include simple bilateral pulmonary vein isolation, the Leipzig lesion pattern, and other patterns.

Alternative ablation technologies may enable surgeons to more widely offer curative procedures for atrial fibrillation. Smaller lesion patterns can be developed from first principals or as a deconstruction of the Maze III or other more extensive pattern. It is possible that atrial fibrillation begins in most people as a disorder of the left atrium. Hence, lesions appropriate for paroxysmal atrial fibrillation (pulmonary vein isolation) could be given to patients with chronic atrial fibrillation to prevent recurrence. FIG. 3A illustrates lesions 40 effecting isolation of the pulmonary veins PV. These lesions abolish paroxysmal atrial fibrillation. The patterns mentioned above, except the Star procedure and the Leipzig lesion pattern isolate the pulmonary veins. Intraoperative measurements of pulmonary vein electrograms pre- and post-ablation to insure electrical silence of the muscle sleeves where triggers are thought to reside may confirm transmurality during application. Data suggests that in fifty percent of patients, effective therapy may be achieved by simply encircling the pulmonary veins with non-conductive lesions.

Lesion patterns may be tailored for the patient. For example, it has been shown that repetitive electrical activity originates in the left atrial appendage in patients with mitral valve disease. Electrical isolation of the left atrial appendage should be strongly considered in these patients. The tri-ring lesion pattern isolates the left atrial appendage, the pulmonary veins, and makes two connecting lesions. Atrial fibrillation associated with right atrial enlargement in congenital heart disease, or atrial flutter following right atrial incisions in congenital heart procedures do not imply the need for such lesions in the majority of patients undergoing atrial fibrillation ablation. The right atrium has a longer effective refractory period than the left atrium and in general sustains only longer re-entry circuits, the most common being the counterclockwise circuit of typical atrial flutter. This can be ablated by a transmural lesions connecting the tricuspid annulus to the IVC. Additional lesions connecting a lateral right atriotomy to the IVC or coronary sinus to the IVC may ablate an atypical right atrial flutter. In general, epicardial ablation may be safer than endocardial ablation because the energy source is directed into the atrial chamber rather than outward into adjacent mediastinal structures.

If bilateral pulmonary vein isolation is the irreducible component of surgical ablation, here is a possible schema for adding additional lesions for a particular patient:

• • 1. If associated with mitral valve disease, include left atrial appendage isolation and left atrial appendage connecting lesion.
  • 2. If known left atrial flutter (rare) include MV, TV, and LA appendage connecting lesions.
  • 3. If known right atrial flutter, giant right atrium, or planned right atriotomy, include ablation lesions from TV to IVC; consider additional lesions from CS to IVC and from atriotomy to IVC.
  • 4. If giant left atrium, consider LA reduction at time of procedure.

The legion pattern may be based on considerations of safety. There is no lesion pattern that is “best” for all patients, but the least complicated lesion pattern that is safe and easy to deliver and shown to be effective for a given population can be considered the best for those patients.

Referring now to FIG. 3B, a standard Maze III procedure has a lesion pattern 42 in heart H as illustrated. A modified Maze III procedure is illustrated in FIG. 3C, having a lesion pattern 44 applied in cryosurgical procedures. In FIG. 3D, a right atrial lesion 46 abolishes atrial flutter that occurs in the right atrium. However, most atrial flutter in the right atrium can be abolished by a single lesion in the isthmus below the OS of the coronary sinus.

Instead of cutting tissue using a Cox-Maze III, or other surgical procedure, and rather than invasive destruction of tissue using a cryoprobes or the like, radiosurgery system 10 (see FIG. 1) provides the ability to target specific foci, regions, lines, and so forth non-invasively. In a preferred embodiment, one could begin with the pulmonary veins, and then iteratively add additional lesions until atrial fibrillation is controlled. The exact doses of radiation will likely differ from patient to patient. A preferred basis for determining dosage is currently known treatment parameters used to produce lesions of similar tissues.

Vascular brachytherapy describes endovascular radiation therapy. Brachytherapy describes the application of radioactivity by a sealed source at a very short distance to the target tissue, e.g., by intracavity or interstitial source placement. The released energy during transformation of an unstable atom into a stable atom is absorbed in tissue. The quantity of absorbed in a tissue is the “dose” with the SI unit Gray (Gy=J/kg). The dose is strongly dependent on the type of radiation and the time span, also called “dwell time.” An application dose rate is the dose of radiation per time (delivered or received). The dose rate delivered by a source depends on the activity of the source and the radionuclide that it contains. Biological effects of the absorbed radiation are dependent on the type of radiation and the type of tissue which is irradiated.

Gamma rays are photons originating from the nucleus of a radionuclide, which take the form of electromagnetic radiation. A heavy unstable nucleus will emit an alpha or beta particle followed by gamma radiation. Gamma rays penetrate deeply within tissues. X-ray radiation is comparable to gamma radiation. Its physical characteristics are similar, however, its origin is from the electron orbit. Beta radiation comprises beta particles, which are lightweight, high-energy electrons with either positive or negative charge. Beta particles can travel only finite distances within tissue, and when slowed by nuclei interactions they give rise to high penetration x-rays.

Absorbed radiation can cause damage in tissue either directly by ionization or indirectly by interacting with other molecules to produce free radicals which will subsequently damage the target. The target is often DNA, so that early and late toxic effects in normal tissue are mainly caused by cell death. Both total radiation dose and dose rate are important, since damage caused by radiation can be repaired between fractionated doses or during low dose rate exposure.

Human aortic cells show a significant decrease in their clonogenic potential after radiation. In injured vascular tissue, radiation doses of 12 to 20 Gy appear to efficacious in inhibiting neointimal formation. Possible high dose radiation effects include antiangiogenic effects and decreases of smooth muscle cells on the adventitia, selective inactivation of smooth muscle cells and myofibrolasts or complete elimination of their proliferative capacity at doses above 20 Gy. Lower dose radiation may promote cellular growth. Hence, promotion of vessel remodeling is dose dependent.

A method for treating a target tissue can be understood with reference to FIGS. 4 and 5. Method 50 for using system 10 is basically a three-step outpatient procedure which consists of scanning 52, planning 54, and treatment 56. Treatment with system 10 begins as the patient undergoes a computer tomography (CT) or magnetic resonance imaging (MRI) as an outpatient. The process may begin with a standard resolution CT scan. MRI scans are optionally used for more accurate tissue differentiation. The patient usually leaves the hospital once the imaging is done. The scan is then digitally transferred to the system treatment planning workstation. Once the imaging is transferred to a workstation, the treatment plan is prescribed. A patient considered for system by treatment 10 may be assessed extensively by a team comprised of a treating neurosurgeon, radiation oncologist, and physicist to determine whether radiation is appropriate and how much. The patient may then undergo percutaneous placement of fiducials or small radiopaque markers that, in conjunction with high quality CT, provide three-dimensional stereotactic localization. The patient then returns several days later for the actual treatment.

On the CT scan, the surgeon and radiation oncologist identify the exact size, shape and location of the target and the surrounding vital structures to be avoided. Once the anatomy has been defined, the system software determines the number, intensity, and direction of radiation beams the robot will crossfire in order to insure that a sufficient dose is administered without exceeding the tolerance of the adjacent tissue. The beams are fired from multiple angles. While some of the radiation may hit surrounding tissues, there is a relatively steep dose gradient. System 10 is capable of treating regions larger than 3-4 cms in diameter. System 10 has been used with motion/respitory tracking software for treating liver and lung tumors where a patient's breathing could slightly distort the targeting of the tumor.

Sophisticated software allows for complex radiation dose planning in which critical structures are identified and protected from harmful levels of radiation dose. System 10 is capable of irradiating with millimeter accuracy. System 10 also has the ability to comprehensively treat multiple lesions. The patient may undergo open surgery and then radiosurgery of the non-operative lesions in one hospitalization.

As an example of the capability system 10, a 52 year old woman was diagnosed with renal cell carcinoma. She was diagnosed with a large metastatic lesion and received 3000 cGy external beam irradiation in 10 fraction. Her pain continued four months later, associated with a left radiculopathy. Radiosurgery with system 10 was recommended.

A large lesion was wedged between the patient's remaining left kidney and the previously irradiated spinal cord. Since the left kidney was her only remaining kidney, the dose was limited to 200 cGy to the kidney, and 300 cGy to the spinal cord. System 10's robotic capability maximized the dose to the tumor and spared the left kidney and spinal cord.

A 30-minute percutaneously fiducial placement procedure was performed one week prior to radiosurgery treatment. The patient was immobilized and a 30 mm collimator was used to treat with a single fraction to a prescribed dose of 1200 cGy that was calculated to the 80% isodose line. The maximum dosage was 1550 cGy, and the tumor volume was 31.3 cc's. Only 0.252 cc of the spinal cord received greater than 800 cGy.

Treatment was tolerated without difficulty or any discernable acute effects and lasted approximately 1 hour. No sedation was necessary and the patient went home that day. The patient reported a significant improvement in pain at her one-month follow-up.

In using system 10 to treat atrial fibrillation, the procedure is pre-planned using a 3D image (CAT, MRI, 3D Echo, etc.) of the patient to sequence the direction and intensity of the radiation to cause the clinical effect precisely in the targeted cells with minimal effect to the surrounding healthy tissue. The typical application relies upon additive effective up to 50 or more passes at a target, directed from different directions so that the more superficial and deeper tissues around the target receive much lower doses. The accumulative effect of the multiple passes may be immediately ablative, or may be sufficient only to provide coagulation and longer term necrosis.

Advantages of the inventive approach over surgical intervention should be immediately apparent. Surgical approaches are necessarily invasive, and are associated with significant morbidity. The distinction applies to even more limited surgical procedures for electrical isolation of discreet atrial regions, including for example, atriotomy, RF ablation, and cryoablation. The inventive subject matter discussed herein provides ways to perform the ablation of ectopic pathways using focused, image-guided, completely non-invasive methods for energy delivery, effecting a complete treatment without the need for surgery or a percutaneous procedure. The procedure may be offered as an iterative treatment permitting minimal treatment, until the desired clinical result is attained. The procedure, being non-invasive, can be offered as an outpatient procedure without the associated need for an anesthetic or pain medication. Patients needing mitral valve repair concomitantly with atrial fibrillation therapy will likely be an early subset due to the potential of fiducial marker placement at the time of the valve intervention. Non-tumor lung treatments may be effected with or without fiducials.

As illustrated in FIG. 4, during a procedure with system 10, a patient P lies still on a treatment table. Generally no sedation or anesthesia is used because the treatment is painless, and the procedure can last anywhere from between 30 to 90 minutes depending on the complexity of the case and the dose to be delivered. The treatment itself involves the administration of numerous radiation beams delivered from different directions, typically in 10 to 15 second bursts. Prior to the delivery of each radiation beam, a stereo pair of x-ray images is taken by image guidance system 16 (see FIG. 1) and compared to the original CT scan (or the like). Between each dose, system 10 uses the information relayed from image-guidance system 16 to adjust robotic arm 14 to the movement of the target, which can be caused by anything from blood flow to the patient breathing. The patient normally leaves the hospital immediately after the treatment is completed, and follow-up imaging is generally preformed to confirm the treatment. System 10 can administer fractionated radiation therapy over the course of several days. Most patients only need one treatment, although some will require treatment with several sessions over several days.

Image-guidance technology is of interest for externally applied radiosurgical techniques to treat cardiac disease. Applicable image-guidance technologies will improve the accuracy of targeting. Dynamic registration of the patient can account for patient movement, even movement of the heart during pumping and breathing.

Advantageously, the novel treatments described herein can be iterative. Rather than target many foci or regions as is often done in an invasive procedure, externally applied radiosurgical techniques can address one or more focus or regions on one day, and the then other foci or regions on another day as needed. The interim period between treatments can be used to access the need for subsequent treatments. Such iterative or fractionated treatment is thus more conservative than current methods.

Suitable types of radiation, including particle beam radiation, may be employed. For example, the present invention encompasses the use of a GammaKnife™ radiosurgery system to ablate ectopic pathways in the atria. Although gamma radiation could be administered during open heart or other invasive procedures, the currently preferred applications are substantially non-surgical.

All suitable radiosurgery system are contemplated with the energy source, duration and other parameters varying according to a size of the patient and other factors. A typical GammaKnife™ radiosurgery system may contain (for example) at least about 200 cobalt-60 sources of approximately 30 curies each, all of which are placed in an array under a heavily shielded unit. The shielded unit preferably comprises lead or other heavy metals.

Gamma radiation may be directed to specific target points at a center of radiation focus. Radiation may be provided during one or more treatment sessions. For example, a dose of 5000 cGy could be delivered within 20 minutes to an effected area defined previously by computer tomography (CT), magnetic resonance imaging (MRI), or angiography.

An image-guided version of a gamma radiation radiosurgery system may also be useful. For example, a camera and/or light or other photo device may be coupled to a portion of the contemplated gamma radiation radiosurgery system. The heart may be beating during the procedure.

Referring now to FIG. 6, radiation treatments may be directed to a diseased, non-functioning lobe 62 of lung L. The radiation may optionally be directed along a line or surface separating the diseased lobe 62 from a healthy and/or functioning lobe 66. The radiation may comprise x-ray beams directed from outside of the patient using a radiation source supported on a robot arm as described above. The diseased lobe 62 may be ablated by the radiation, and/or the radiation may isolate the diseased lobe 62 from the functioning portion of the lung 66. The radiation may be directed to the target line 64 so as to inhibit collateral injury to adjacent tissues, including esophagus E. Treatments may be applied to one or more regions of one or both lungs of the patient, and may be effected iteratively as described above.

The radiation treatments of the present invention may be used in conjunction with minimally invasive devices for isolating one or more regions of the lung. Suitable devices may include those described in U.S. Patent Application Publication No. U.S. 2003/0181922 A1, published on Sep. 25, 2003 and entitled “Removable Anchored Lung Volume Reduction Devices and Methods;” PCT Application WO 03/075796 A2, published on Sep. 18, 2003 and entitled “Methods and Devices for Inducing Collapse in Lung Regions Fed by Collateral Pathways;” and U.S. Pat. No. 6,629,951, issued on Oct. 7, 2003 and entitled “Devices for Creating Collateral in the Lungs,” the full disclosures of which are incorporated herein by reference. These references also provide additional information on disease states suitable for treatment with the non-invasive radiation devices and methods described herein, and on the physiology of the treatment regions. However, as the present radiation methods and systems can be used with or without these related treatments and devices, these disclosures need not be limiting on all embodiments of the present invention.

While the exemplary embodiments have been described in some detail, by way of example and for clarity of understanding, those of skill in the art will recognize that a variety of modification, adaptations, and changes may be employed. For example, multiple energy sources may be employed, including laser or other photoenergy sources, in combination with one or more forms of radiation. Hence, the scope of the present invention may be limited solely by the appending claims.

Claims

1. A method for treatment of a lung of a patient, the method comprising: directing radiation from outside the patient toward one or more target treatment regions in the lung so as to inhibit chronic obstructive pulmonary disease of the lung.

2. The method of claim 1, wherein the radiation from outside the patient toward a target lobe of the lung, wherein the lung does not have a tumor.

3. The method of claim 2, wherein the radiation effects ablation of the one or more target treatment regions.

4. The method of claim 1, wherein the radiation is delivered so as to avoid exceeding a tolerance of tissues adjacent the one or more target regions.

5. The method of claim 1, wherein the radiation is delivered as a series of radiation beams extending toward the heart from different angles.

6. The method of claim 5, further comprising dynamically registering the radiation beams with the one or more regions of the lung.

7. The method of claim 6, wherein the dynamic registration is performed so as to compensate for movement of the lung.

8. The method of claim 6, wherein the dynamic registration is performed so as to compensate for movement of the patient and breathing.

9. The method of claim 6, further comprising moving a radiation source around the patient with a robot arm and directing the radiation toward the region of the lung from the radiation source along the series of radiation beams.

10. The method of claim 5, further comprising acquiring a plurality of target adjustment images during the radiation treatment procedure, and determining a position of the region relative to a reference frame of the robot from the target adjustment images.

11. The method of claim 10, further comprising inserting radiopaque fiducial markers into the patient around the region, wherein the target images are acquired with first and second fluoroscopic systems.

12. The method of claim 10, wherein the target adjustment images are acquired between delivery of successive radiation beams.

13. The method of claim 9, wherein the robot arm moves the source with six degrees of freedom.

14. The method of claim 5, further comprising scanning patient anatomy so as to identify the target region, and planning the series of radiation beams.

15. The method of claim 14, wherein scanning the patient anatomy comprises a CT scan.

16. The method of claim 14, wherein scanning the patient anatomy comprises an MRI scan.

17. The method of claim 14, wherein planning the series of radiation beams comprises determining a number, intensity, and direction of the radiation beams.

18. The method of claim 14, wherein the target region comprises determining a target region shape, wherein the radiation is delivered so as to effect a non-isocentric treatment.

19. The method of claim 1, further comprising generating the radiation with a portable linear accelerator, the radiation comprising x-ray radiation.

20. The method of claim 1, wherein the radiation comprises gamma radiation.

21. The method of claim 1, further comprising minimizing damage to surrounding tissue.