US 20060225742 A1
Apparatus for providing intrabronchial delivery of neurotoxins to control the effects of asthma comprises a shaft having proximal and distal ends and a neurotoxin applicator assembly disposed on the distal end. The neurotoxin applicator assembly comprises a deployable needle assembly, a rotating needle assembly, and a needle-less injection assembly or a nebulizer assembly.
1. Apparatus for intrabronchial delivery of medication to treat lung disease, the apparatus comprising:
a shaft having a proximal end including at least one inlet port, a distal end and a lumen extending between the inlet ports and the distal end; and
a medication applicator comprising a needle assembly disposed on the distal end of the shaft in fluid communication with the lumen.
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The present application is a continuation of U.S. patent application Ser. No. 10/437,882 (Attorney Docket No. 020979-003600US), filed May 13, 2003, the full disclosure of which is incorporated herein by reference.
The present invention relates to apparatus for treating asthma by controlled delivery of neurotoxin 5 using a neurotoxin applicator assembly.
The lung is made up of progressively smaller bronchial bifurcations stemming downward from the trachea. The trachea and proximal bronchi are lumens consisting of an outer layer of fascia surrounding a U-shaped inner cartilaginous layer, wherein the open portion of the U is spanned by smooth muscle. Inside the cartilaginous layer are a collagenous elastic layer and an innermost epithelial layer. Mucus secreting goblet cells and transport cilial cells are interspersed within these inner layers.
As the bronchi branch and get smaller, the cartilaginous layer changes from a U-shape to irregular and helical shapes. In addition, the smooth muscle layer becomes helical bands surrounding the entire circumference of the bronchi, the goblet cells gradually decrease in numbers and the ciliated cells get smaller and fewer in number. In the most distal bronchi, the outer cartilaginous layer disappears completely, the smooth muscle layer becomes the outermost layer and goblet cells and ciliated cells disappear completely.
Asthma is a complex disease of the bronchial tree, characterized by airway hyperresponsiveness to allergens, stress and environmental triggers. Environmental triggers include irritants such as pollutants and non-allergenic triggers such as exposure to cold air. Airway hyperresponsiveness results in acute narrowing of the entire bronchial tree reducing airflow through the lungs, compromising respiration and limiting gas exchange in the alveoli. The narrowing of the bronchial tree is a result of three basic characteristic physiologic responses: (1) smooth muscle contraction; (2) increased mucus production; and (3) edema caused by arterial dilatation and increased arterial permeability. The triggering mechanisms for these physiologic responses are part of the body's inflammatory response system.
Chronic uncontrolled asthma can result in structural changes to the bronchial wall itself. Smooth muscle hyperplasia results in thickening of the smooth muscle components of the bronchial wall. Thickening of the subepithelial collagen layer that lies between the airway epithelium and the smooth muscle layer results in progressive stiffening of the wall of the bronchi. Studies have shown that stiffening of the airway wall results in more profound narrowing of the airway for a given asthma attack. This is due to changes in the ability of the mucosal layer to fold in response to the smooth muscle layer contraction.
Recently, the controlled injection of neurotoxin has become a common procedure for controlling skeletal muscle spasms. A frequently used neurotoxin for this procedure is the botulinum toxin, serotype A, sold commercially by Allergan, Inc. as BOTOX®. BOTOX® neurotoxin blocks the release of neurotransmitter from the nerves that control the contraction of the target muscles. Many applications for BOTOX® neurotoxin have been proposed and/or clinically tested, including cervical dystonia, cosmetic relief of frown lines and tremor associated with cerebral palsy. Recently, BOTOX® neurotoxin has become the subject of clinical study for the relief of hyperhidrosis (profuse sweating) and hypersalivation. These studies indicate that BOTOX® neurotoxin can be used to control the action of cholinergic parasympathetic nerves as well as large skeletal muscle groups. The recent findings open the possibility of using neurotoxins such as BOTOX® neurotoxin to control some of the main mechanisms of airway narrowing in asthmatic attacks, specifically smooth muscle contraction and hypersecretion of mucus from the goblet cells. Additionally, there is evidence that some part of the inflammatory response of asthma is stimulated by the release of the neurotransmitters which BOTOX® neurotoxin inhibits. This opens the possibility that BOTOX® neurotoxin may also work to mitigate the inflammatory cycle itself.
The use of neurotoxin for the control of asthma is described in U.S. Pat. No. 6,063,768 to First, wherein asthma is included in a list of neurogenic inflammatory disorders that may be controlled through the action of neurotoxins such as BOTOX® neurotoxin. That patent also describes that BOTOX® neurotoxin could be aerosolized and introduced into the lungs. An earlier patent, U.S. Pat. No. 5,766,605 to Sanders, et al. describes the use of BOTOX® neurotoxin to treat asthma and COPD, but does not describe the methods or devices used to do so. Further mention of BOTOX® neurotoxin in connection with asthma is provided in a press release dated Feb. 7, 2003 by the University of Alberta in describing the work of Dr. Redwan Moqbel. The release mentions that Dr. Moqbel and others are researching the possible use of neurotoxins such as tetanus and botulinum toxin to prevent eosinophils from activating and starting the inflammatory cascade that results in an asthma attack.
While it may be possible to simply aerosolize neurotoxins for introduction into the lungs, introducing it into the patient through traditional inhalation means would expose the mouth, tongue, epiglottis, vocal cords, etc. to the actions of the neurotoxin, with obvious deleterious results. Much more controlled and direct application of the neurotoxin to the desired tissue is required for safe and effective therapy.
Accordingly, it would be desirable to provide apparatus that enables controlled delivery of a neurotoxin to target treatment areas within a patient's bronchial airways.
It also would be desirable to provide an apparatus permitting the controlled injection of neurotoxin into the bronchial wall of a patient.
It would further be desirable to provide a needle-less injection apparatus to eliminate potential complications related to the presence of needles within a patient's bronchial airways.
Additionally, it would be desirable to provide an apparatus permitting the application of neurotoxin onto a target treatment area within a patient's bronchial airways.
In view of the foregoing, it is an object of the present invention to provide apparatus that enables the controlled delivery of a neurotoxin to target treatment areas within a patient's bronchial airways.
It is a further object of the present invention to provide an apparatus permitting the controlled injection of neurotoxin into the bronchial wall of a-patient.
It is an additional object of the present invention to provide a needle-less injection apparatus to eliminate potential complications related to the presence of needles within a patient's bronchial airways.
It is another object of the present invention to provide an apparatus permitting the application of neurotoxin onto a target treatment area within a patient's bronchial airways.
These and other objects of the present invention are accomplished by providing an intrabronchial neurotoxin delivery system for controlled delivery of neurotoxin to a target treatment area within a patient's bronchial airways to lessen the effects of asthma. The introduction of neurotoxin into the bronchial airways disables the hyperresponsive smooth muscle layer and controls the hypersecretion of mucus.
The intrabronchial neurotoxin delivery system preferably includes a bronchoscope and neurotoxin applicator assembly. The neurotoxin applicator assembly may be a needle assembly, rotating needle assembly, needle-less injection assembly or a nebulizer assembly.
In a first illustrative embodiment, the neurotoxin applicator assembly comprises a needle assembly including at least one needle having a lumen in fluid communication with a source of liquid neurotoxin. The needles are preformed to contract radially when disposed within a lumen, such as a lumen of the bronchoscope, but may be extended to penetrate and inject small doses of neurotoxin into the bronchial wall of a patient.
In an alternative embodiment, the neurotoxin applicator assembly comprises a rotating needle assembly including plural needles disposed along the circumference of a wheel. Again, the needles include lumens in fluid communication with a source of liquid neurotoxin. In operation, the wheel is adapted to be rolled across a target treatment area about a central hub. Optionally, the rotating needle assembly may include a fender to protect a portion of the bronchial wall substantially opposite the target treatment area.
In another alternative embodiment, the neurotoxin applicator assembly comprises a needle-less injection assembly including a shaft having at least one port in fluid communication with a source of liquid neurotoxin. The needle-less injection assembly can be used to inject neurotoxin into the bronchial wall without needle penetration. Optionally, an inflatable balloon may be provided to help position the at least one port adjacent the target treatment area.
In yet a further alternative embodiment, the neurotoxin applicator assembly comprises a nebulizer assembly including an atomizer in fluid communication with a source of liquid neurotoxin. The atomizer converts the liquid neurotoxin into a fine spray or mist that is directed onto the target treatment area. The particle size of the mix can be controlled using injection pressure or atomizer head design to access specific portions of the lung adjacent to or downstream of the treatment device. An inflatable balloon optionally may be provided to facilitate positioning the atomizer adjacent the target treatment area. The balloon also serves to isolate the lung segment downstream of the device to prevent reflux of the mist into undesired portions of the airway. In addition, lumens optionally may be disposed between the balloon and atomizer to provide a ventilation system that allows pressure control of the treatment area to prevent over-inflation of the lung, mixing of the atomized fluid, and evacuation of remaining mist at termination of therapy, prior to balloon deflation.
The above and other objects and advantages of the present invention will be apparent upon consideration of the following detailed description, taken in conjunction with the accompanying drawings, in which like reference characters refer to like parts throughout, and in which:
In accordance with the principles of the present invention, neurotoxin applicator assembly 20, of which various illustrative embodiments are described hereinbelow, enables the physician to selectively administer controlled doses of neurotoxin to or within selected treatment sites in the patient's lung. More specifically, neurotoxin applicator assembly 20 may be selectively advanced through lumen 14 of bronchoscope 10 to deliver a neurotoxin, such as botulinum toxin, serotype A, to a target treatment area.
Neurotoxin applicator assembly 20 includes shaft 21 coupled to at its proximal end to handle 22, distal end 23 having neurotoxin applicator 24, and lumen 25. Lumen 25 provides fluid communication between proximal end and handle 22 and applicator 24. Syringe 26 having plunger 27 is coupled to a port on proximal end 22. Syringe 26 is filled with neurotoxin in liquid form, and applies the neurotoxin to applicator 24 via lumen 25 when plunger 27 is actuated.
Handle 22 enables the physician to extend and retract applicator 24 from within lumen 14 of bronchoscope 10, and to manipulate distal end 23 of neurotoxin applicator assembly 20 under direct visual observation using the optics of bronchoscope 10. The neurotoxin applicator assembly preferably remains retracted within lumen 14 of the bronchoscope during insertion of the catheter into the patient's bronchial airways, and is deployed once the applicator is in a desired position. Alternatively, applicator 20 may be housed inside of a retaining sheath, and both units can be advanced through lumen 14 together.
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When needle assembly 30 is deployed, as illustrated in
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Suitable needles materials for needle assembly 28 of
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Needle-less injection assembly 46 comprises shaft 47 including at least one port 48 in fluid communication with lumen 25. Inflatable balloon 49 optionally may be coupled to shaft 47, and used to position the shaft adjacent target treatment area T. Balloon 49 is inflated with a fluid introduced through a lumen of shaft 47. When the shaft is aligned with the target treatment area, pulses of pressurized gas may be employed to inject predetermined amounts of neurotoxin across the airway wall and into the collagenous and smooth muscle layers.
With respect to
Nebulizer assembly 50 may also include optional inflatable balloon 52 disposed on shaft 55 proximal of atomizer 51. Selective inflation of balloon 52 allows positioning of atomizer 51 so that aerosolized neurotoxin may be directly sprayed onto target treatment area T. Balloon 52 also acts to isolate the treatment area from the rest of the lung, preventing reflux of mist into unintended areas. As for the embodiment of
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Although preferred illustrative embodiments of the present invention are described above, it will be evident to one skilled in the art that various changes and modifications may be made without departing from the invention. It is intended in the appended claims to cover all such changes and modifications that fall within the true spirit and scope of the invention.