1. Field of the Invention
This invention concerns generally a drug and device combination system used in a method for treatment of severe and oral corticosteroid-dependent asthma and other respiratory diseases requiring a treatment with orally administered steroids. The method comprises administration of an inhalable corticosteroid drug by a flow rate and volume regulated inhalation wherein the inhalable corticosteroid is administered predominantly into a target area of the lungs, in particular the small airways of the lungs, using a system comprising an inhalable drug and device combination. The system permits fine tuning of the flow of the inhalable corticosteroid drug into the lungs in an optimized volume to secure a maximal and reproducible corticosteroid dose deposition into the lung target area. Both the method and the system are safe, efficacious, reproducible, controllable and individually programmable to assure treatment safety and compliance. The device's capability to control flow rate and inhalation volume assures delivery of the inhalable drug directly to the target area of the lungs and thereby minimizes the drug dose requirement of oral steroids while at the same time it maximizes the drug dose deposition in said target areas, assures the dose reproducibility, decreases drug waste and eliminates or greatly reduces side effects.
The drug and device combination system has unexpectedly large clinical benefits. When the patients are treated with this system according to the method of the invention and when the protocol of the invention for inhalable corticosteroids delivery is followed, the use of the drug and device combination system results in a complete weaning of the patients from oral corticosteroids in at least 50% of all treated patients, or in a partial weaning to ≦50% of the initial oral corticosteroid dose in about 80% of all treated patients. Concurrently, it results in a substantial improvement of FEV1—as well as in a clinically meaningful improvement of Quality of Life of these patients. There is a decreased degree of symptoms exacerbation and a decreased need for hospitalization. The device that provides a controlled and regulated flow rate and volume during inhalation assures a more homogeneous peripheral deposition of the drug, and its individually tailored programming based on the patient's health conditions provides a feedback regarding the adherence to the treatment protocol.
The method and system of the invention are particularly suitable for delivery of inhalable corticosteroids into the peripheral small airways of the lungs for treatment of severe and oral corticosteroid-dependent asthma and other respiratory diseases requiring treatment with oral corticosteroids, without the need for simultaneous administration of oral corticosteroids or with a significantly decreased need for such simultaneous administration of oral corticosteroids. The controlled flow rate and volume system significantly increases delivery of the drug and selectively delivers the aerosolized inhalable corticosteroid into the small airways, particularly to terminal and respiratory bronchioles and alveolar ducts and sacks of the peripheral lungs. It further eliminates or significantly decreases deposition of the corticosteroid into the larger bronchioles, bronchi and trachea of the upper lungs as well as into the oropharyngeal area and thereby substantially decreases or completely eliminates undesirable secondary symptoms, such as mouth irritation, thrush, oral candidiasis, hoarseness, soreness, upper respiratory tract infection, laryngitis, voice alterations or other oropharyngeal problems typically associated with delivery of inhalable corticosteroids. The method utilizes inhalation devices comprising components for individualization of treatment parameters in patients having compromised breathing pattern due to severe and oral corticosteroid-dependent asthma or another severe respiratory disease, and for assurance of compliance and safety.
The method of the invention includes a step of complete or at least partial weaning of a patient from orally administered steroids and replacing them with much lower doses of inhalable corticosteroids, wherein the unique drug and device combination results in an unexpectedly large improvement of pulmonary function, improvement in Quality of Life, particularly in asthmatic patients, unexpected and substantial reduction of symptom exacerbations, reduction in occurrence and length of hospitalizations and in recovery of endogenous hydrocortisone (cortisol) production.
2. Background and Related Disclosures
Asthma and particularly severe oral corticosteroid-dependent asthma is a chronic inflammation of the bronchial tubes of airways that causes swelling, bronchial narrowing and constriction resulting in severe breathing obstructions in asthmatic patients. The severe form of asthma is connected with bronchial hyper-reactivity and with chronic severe and oral corticosteroid-dependent asthmatic symptoms. Other respiratory diseases that require treatment with orally administered corticosteroids experience similar symptoms. Such symptoms are generally treated with orally administered or inhalable drugs, preferably with oral or inhalable steroids and corticosteroids suitable for inhalation therapy.
Global Initiative for Asthma (GINA) asthma guidelines has been established to determine severity of the asthma. Severe and oral corticosteroid-dependent asthma is classified by GINA guidelines as steps IV and V. For step IV, the preferred treatment is to combine medium to high doses of inhaled corticosteroid with a long-acting inhaled β-agonists. For step V, the above medication is further supplemented with orally administered corticosteroids. Both treatments are known to cause or to be associated with severe side effects, which exacerbate with a continuous and extended use of high doses of inhaled corticosteroids.
Successful treatment and management of severe asthma and other respiratory diseases is often dependent on orally administered corticosteroids. Severe oral corticosteroid-dependent asthma and other respiratory diseases require treatments with high doses of orally or intravenously administered steroids that are chemically and functionally similar to hydrocortisone hormones produced by the adrenal glands. However, the long-term use of these corticosteroids leads to serious undesirable side effects, such as truncal obesity, glaucoma, acceleration of cataract formation, high blood pressure, an increased risk of diabetes due to glucose intolerance and of osteoporosis due to bone mineral loss, psychological effects, growth suppression in children and adrenal suppression. These side effects have been linked with cortisol suppression, especially when dose levels of systemically administered corticosteroids are high.
Many attempts have been made to control asthma with a particular emphasis on the control and treatment of patients suffering from the severe and oral corticosteroid-dependent asthmatic attacks. However, since each individual is unique in his/her degree of reactivity to environmental triggers, asthma affects each patient differently. This naturally influences the type, dose and route of administration of various medications and treatments.
The currently available treatments for asthma are largely dependent on the severity of the disease. In most cases (GINA step II-V), these treatments involve administration of steroids, such as orally administered corticosteroids (OCS), such as prednisone or prednisolone, or inhalable corticosteroids (ICS), such as fluticasone, beclomethasone, budenoside, mometasone, ciclesonide, flunisolide or triamcinolone acetonide, in a therapeutic dose. These treatments may be supplemented with other drugs, such as, for example, bronchodilators such as β-agonists. Since orally or otherwise systemically delivered corticosteroids affect the whole body and cause rather severe adversary side effects and secondary symptoms, locally administered corticosteroids by inhalation are highly preferred as a current treatment for asthma.
Corticosteroids, also called glucocorticoids, are powerful drugs that quickly reduce inflammation and pain. However, the corticosteroids benefit is often negated by severe side effects observed during extended administrations of corticosteroids needed for treatment of recurring respiratory diseases such as, for example, severe and oral corticosteroid-dependent asthma. To maximize benefits of corticosteroids, but minimize their potential side effects, these drugs are usually prescribed in doses as low as possible and/or only for a short duration of time. Since the severe and oral corticosteroid-dependent asthma requires repeated administration of inhalable corticosteroids, there is a real danger of developing side effects such as mouth irritation, thrush, oral candidiasis, hoarseness, sore throat, coughing, upper respiratory tract infections, laryngitis or other oropharyngeal problems as well as other serious adverse reactions tiding osteoporosis, increased mortality, poisoning from the overdose of corticosteroids or exogenous Cushing's syndrome.
Moreover, when the administration of corticosteroids is stopped or decreased too rapidly, a life-threatening acute adrenal crisis may develop because the adrenal glands of the patient are unable to produce their own hormones fast enough. Acute adrenal crisis is a state caused by insufficient levels of the steroid hormone hydrocortisone (cortisol) also called stress hormone, produced by the zona fasciculata of the adrenal gland that is released in response to any stress situation. Risk factors for acute adrenal crisis include physical stress such as infection, trauma or surgery, adrenal gland or pituitary gland injury, and premature termination of treatment with steroids.
It would therefore be advantageous to have available a method and means for replacement, or at least reduction, of orally administered corticosteroids, including weaning of the patients of corticosteroids. Such method would be particularly useful for treatment of those patients suffering from severe and oral corticosteroid-dependent asthma and who are in need of a continuous corticosteroid treatment. It would further be advantageous for reduction of side effects associated with administration of large dosages of corticosteroids, if the dose of corticosteroids administered via inhalation could further be reduced by improved targeting of aerosolized drug particles to the small airways of the deep, peripheral lung.
As indicated already above, many attempts to successfully treat severe and oral corticosteroid-dependent asthma have been made. These attempts include development of new and more potent drugs, such as for example more potent corticosteroid fluticasone as well as new nebulizing technologies that affect pulmonary drug delivery.
Eur. J. Clin. Pharmacol., 57:637-41 (2001) describes a study comparing a large volume spacer and fluticasone nebulizer (FP-neb) in delivery of fluticasone propionate by inhalation in healthy volunteers. The large volume (750 ml) spacer was shown to produce about a sevenfold higher relative lung dose than nebulizer. This reference shows that the efficacy of the aerosol delivery depends on the device used for such delivery.
Respir. Med., 93(10):689-99 (1999) describes the oral steroid-sparing effect of a high dose (4000 μg/day/bid) and a lower dose (1000 μg/day/bid) of inhaled fluticasone propionate. The nebulized fluticasone at a daily dose between 1 mg (1000 μg) and 4 mg (4000 μg) was a safe and effective means for reducing the oral steroids requirement of patients with chronic oral dependent asthma. The reduction in the need for orally administered prednisone was significantly greater in the group receiving 4000 μg of fluticasone propionate per day than 1000 μg per day. However, a high percentage (37%) of all patients discontinued the 4000 μg treatment, presumably for high occurrence of severe side effects.
J. Allergy Clin. Immunol., 103:267-75 (1999) describes an oral corticosteroids-sparing effect and improved lung function in patients with severe chronic asthma who received 500 or 1000 μg of fluticasone propionate administered twice daily. While this treatment eliminated a need for oral prednisone, topical adverse effects associated with inhaled corticosteroids were observed during this treatment.
Br. J. Clin. Pract., 48:15-8 (1994) assessed a long-term safety of fluticasone propionate in asthmatic children. Adverse effects were reported by 51% of patients even with such low doses as 50 or 100 μg administered twice a day via a dry powder inhaler.
Cochrane Database Syst. Rev., (2004), Issue 3, Art. No.:CD002310 reviewed a potency of fluticasone propionate for treatment of chronic asthma and compared its effect to that of beclomethasone and budenoside. The study showed that fluticasone propionate, given at half the daily dose of beclomethasone or budenoside, resulted in improvement of forced expiratory volume in the first second (FEV1). Unfortunately, due to a larger deposition of the fluticasone in the upper lungs, it also had a higher risk of pharyngitis and other adverse side effects.
Cochrane Database Syst. Rev., (2005), Issue 3, Art. No.: CD003534 describes use of inhaled fluticasone at different doses. While patients receiving 2000 μg per day of fluticasone propionate were more likely to reduce a need for oral prednisolone then those on 1500 or 1000 μg/day, hoarseness and oral candidiasis were significantly greater for these higher doses.
Cochrane Database Syst. Rev., (2003), Issue 4, Art. No.: CD004109 investigated high dose versus low dose inhaled corticosteroid as initial starting dose for asthma in adults and children. 2000 μg fluticasone was administered once a day using AKITA protocol. This dose resulted in FEV1 improvement of 17.1% and reduction in oral steroid use of 33.2%. It was estimated that of the administered dose only 500-700 μg reached the central portion of the lungs, the same amount remained in the nebulizer and the remaining corticosteroid was deposited in oropharynx or exhaled. Although the FEV1 was improved with this high dose of fluticasone, the loss of the drug was approximately two-thirds of the total dose, with one third remaining in the nebulizer and one-third deposited in oropharynx thereby resulting in undesirable side effects.
Respiratory Medicine, 94: 1206-1214 (2000) investigated the efficacy and safety of nebulized fluticasone propionate compared to orally administered prednisolone. The nebulized fluticasone was at least as effective as oral prednisolone in the treatment of children with acute exacerbated asthma.
Annals Allergy, Asthma and Immunology, 92:512-522 (2004) reviewed the efficacy and safety of inhaled corticosteroids when used to reduce daily oral corticosteroid requirement in patients with severe asthma. Authors concluded that inhalable corticosteroid can reduce orally administered corticosteroids requirements in patients with persistent and exacerbated asthma. However, the question of increased adverse side effects still remains.
The US patent application publication No.: 20050087189 A1 describes an inhalation device which emits aerosol only during the first half of the patient's inspiration time which is used to administer budesonide to asthmatic children. The results suggested that lower daily doses could be used and that the compliance was better than in case of nebulizers which emit aerosol continuously. However, US 20050087189 A1 does not disclose any flow rate and/or volume control of the device. It is further not disclosed that any of the children could be weaned from any orally administered corticosteroids partially or completely, using the device and method described in US 20050087189 A1.
Respir. Med., 86(2):105-8 (1999) demonstrated, in an open label-study, that a nominal dose of 4-8 mg budesonide daily, given via conventional nebulizer (which was not specified in the publication) will, over a period of 12-18 months, lead to steroid weaning in 14 of the 18 subjects studied. There were also only moderate improvements in pulmonary function, along with a reduction of the mean annual number of asthma exacerbations requiring hospitalization, from 1.5 to 0.9 per year. The relatively high dose (up to 8 mg) and volume in the nebulizer (16 mL) will demand very long inhalation times of more than 30-35 min per treatment. In addition, side effects like oral thrush or disturbing sore throat occurred in 11% of the subjects treated. Milder side effects such as hoarseness and mild thrush were also reported, but not quantified.
The above discussed disclosures concern administrations of steroids to asthmatic patients and efficacies thereof in reducing the concurrent use of orally administered steroids. These disclosures indicate that the need for orally administered steroids in patients suffering from severe and oral corticosteroid-dependent asthma may be decreased by administration of appropriately high doses of inhalable corticosteroids. However, when such high doses of inhalable corticosteroids are administered, severe adverse side reactions still occur, preventing a truly efficacious treatment of these patients.
It would be therefore advantageous to have available a controlled system comprising a drug and device combination and a method including a treatment protocol that would assure compliance with preset treatment conditions. Such system would provide and assure delivery of an efficacious dosage of the inhalable corticosteroid to small airways of the deep peripheral lung predetermined target area, without at the same time depositing the drug in oropharyngeal area in order to reduce or eliminate undesirable adverse side reactions and secondary symptoms. Clearly, such system would depend on the exclusive and precise delivery of these drugs to said target area of the lungs and also on inhalation devices and apparatuses used for such delivery. Numerous attempts were made to provide devices for precise administration of drugs to the lungs; however, these attempts lack efficacy, targeted delivery to deeper lung areas, elimination of adverse reactions and individualization of such treatment.
In this regard, U.S. Pat. No. 6,606,989 discloses a device for precise administration of medicated aerosol to the lungs. The device comprises of an inhalation mouthpiece; a pressure sensor responsive to a suction pressure to produce a triggering signal; an adjustable vaporizer coupled to the inhalation mouthpiece containing the inhalable fluid that issues frequencies to deliver the vaporized fluid to the mouthpiece; a compressed-air control valve responsive to a valve signal to provide a predetermined inhaled volume; a volumetric flow controller coupled to the compressed-air control valve to preset a determined quantity of a volumetric flow of the nozzle flow; a flow meter for control of a predetermined volumetric flow; and an electronic controller that receives the triggering signal from the pressure sensor to produce the valve signal and the vaporizing signal. The electronic controller is configured with a pre-settable vaporizing period and a pre-settable pause interval. It further controls the high frequencies issued by the vaporizer and is operable to set the vaporizing period of the adjustable vaporizer to an invariable value from opening of the compressed-air control valve and causes a predetermined volume to be emitted at the device's mouthpiece for each respiratory maneuver. While this disclosure certainly provides a useful device for inhalation, it lacks the aerosol having a limited particle size range permitting targeted delivery of the drug into the peripheral lungs and does not provide an individual control for compliance with the drug delivery protocol. Moreover, U.S. Pat. No. 6,606,989 does not disclose any specific values for flow rate and/or volume which would improve the deposition of aerosolized particles in the target area of the lower lungs, in particular the small airways.
J. Physiol. Pharmacol., 58 (Supp1.5): 615-625 (2007) describes novel approaches to enhance pulmonary delivery of proteins and peptides. This article describes importance of a number of biophysical and physiological parameters that have to be considered when the delivery of proteins and peptides into systemic circulation is contemplated. Among these parameters are particle diameter, particle density, hygroscopicity, electrical charge, chemical properties of the drug, age of the patient, pulmonary disease, breathing pattern, all of which affect the mechanism of pulmonary drug deposition. The article discloses one type of the AKITA® inhalation systems that guides the patient through the inhalation maneuver and ensures an optimized particle deposition.
For treatment of severe and oral corticosteroid-dependent asthma, the above devices might be somehow useful; however, to achieve the reduction or elimination and weaning of the patient from the orally administered corticosteroids, these devices are not efficacious enough without further modifications, adjustments, additional components and without a precise protocol for inhalable corticosteroids delivery.
It would, therefore, be advantageous to have available a combination system including an inhalation device, an inhalable corticosteroid and a method that would provide efficacious treatment for severe and oral corticosteroid-dependent forms of asthma with an efficacious dose of said inhalable corticosteroid selectively deposited at a site of asthmatic inflammation, namely in alveoli and bronchioles of the small airways of the lower, peripheral lungs, combined with no or low deposition of the corticosteroid in the nose, mouth, throat, oropharyngeal area, larger bronchioles, bronchi, and trachea, wherein the need for concurrent orally administered steroids could be eliminated or the need for the oral dose of these drugs could be at least significantly reduced in the oral corticosteroid-dependent asthma patient population. As a consequence, the oropharyngeal side effects enumerated above will be reduced.
It is, therefore, a primary object of this invention to provide a combination system including an inhalation device, an inhalable corticosteroid, a method for treatment and a protocol for precise and efficacious delivery of said inhalable corticosteroid into the small airways of the lungs for the treatment of severe and oral corticosteroid-dependent forms of asthma and other respiratory diseases. The system delivers a sufficiently high dosage of the inhalable corticosteroid to treat these conditions, including severe and corticosteroid-dependent asthma, to permit either a complete elimination and weaning of the patients from oral corticosteroids in at least 50% of all treated patients or reduction of the oral corticosteroid dose in about 80% of all patients, with a mean reduction of the initial dose of about 75%. Additionally, said system achieves a maximal deposition of the inhalable corticosteroid in the lower, peripheral lung, controlled dose reproducibility, reduced variability of lung dose deposition and minimization of side effects. The system delivers the corticosteroids selectively into the small airways of the peripheral lungs (also called lower lungs) of an asthmatic patient without depositing said inhalable corticosteroid into the upper lungs, trachea, mouth, nose or oropharyngeal cavity, and thus without causing undesirable side effects, and it greatly improves the physiological parameters of treated patients.
One aspect of the current invention is a drug and device combination system used in a method for treatment of severe and oral corticosteroid-dependent asthma and other respiratory diseases that require a concurrent treatment with orally or otherwise systemically administered corticosteroids wherein said treatment with said system results in either complete weaning from or substantially decreased use of said orally administered corticosteroids in a patient suffering from severe and oral corticosteroid-dependent asthma or another respiratory disease.
Another aspect of the current invention is a drug and device combination system providing means for increased efficacy of an inhalable corticosteroid treatment by delivering therapeutically effective dosages of inhalable corticosteroid selectively to small airways, including terminal bronchioles, respiratory bronchioles, alveolar ducts and alveolar sacs of the lower lungs of a patient suffering from severe and oral corticosteroid-dependent asthma, without causing adverse side effects and secondary symptoms by incidental delivery of these corticosteroid to a mouth or nose cavity, throat and upper lungs.
Another aspect of the current invention is a drug and device combination system having unexpectedly large clinical benefits in treatment of patients suffering from severe asthma or another respiratory disease that requires concomitant oral corticosteroid treatment in that that when these patients are treated with the system according to the method of the invention and following the protocol of the invention for inhalable corticosteroid delivery, such treatment results in a complete weaning of the patients from oral corticosteroids in at least 50% of all treated patients, or in a partial weaning to ≦50% of the initial oral corticosteroid dose in about 80% of all treated patients, said treatment additionally resulting in a substantial improvement of FEV1 after 18 weeks of treatment, such as by more than 16% in the group treated with the full dose of budesonide (1 mg), in improvement of Quality of Life of these patients, in a decreased degree of symptoms exacerbation and a decreased need for hospitalization, and wherein the system's device provides a controlled and regulated flow rate and volume during inhalation that assures more homogeneous peripheral deposition of the drug in the small airways of the lungs and wherein said device also provides individually tailored programming to the patient's health conditions and at the same time provides a feedback for and assures the adherence of the patient to the treatment protocol.
Still another aspect of the current invention is a drug and device combination system used in a method for treatment of severe and oral corticosteroid-dependent asthma wherein said device of the system regulates the flow rate and volume of the aerosol containing the inhalable corticosteroid, thereby resulting in the delivery of said inhalable corticosteroid predominantly into a target area of the lower lungs, in particular the small airways, thereby resulting in delivery of said inhalable corticosteroid in efficacious quantity sufficient for a complete weaning of the patient from the orally administered corticosteroid drugs and hence elimination of the need for use of such orally administered drugs in at least 50% of all treated patients.
Still yet another aspect of the current invention is a drug and device combination system used in a method for treatment of severe and oral corticosteroid-dependent asthma wherein said device of the system regulates the flow rate and volume of the aerosol containing the inhalable corticosteroid, thereby resulting in the delivery of said inhalable corticosteroid predominantly into the target area of the lower lungs, in particular the small airways, and thereby resulting in delivery of said inhalable corticosteroid in efficacious quantity that is sufficient for at least 50% reduction of the initial oral corticosteroid dose in about 80% of all treated patients suffering from severe and oral corticosteroid-dependent asthma or from another corticosteroid-dependent respiratory disease.
Still yet another aspect of the current invention is a drug and device combination system used in a method for treatment of severe oral corticosteroid-dependent asthma wherein said device of the system regulates the flow rate of the aerosol to about 100-400 ml per second, preferably 200 ml per second, and wherein said device of the system regulates the inhalation volume to about 400-2000 ml, preferably between about 1000 ml and about 2000 ml, most preferred about 1400 ml, by using an electronically controlled inhalation system, optionally with overpressure from about 0.1 mbar up to 40 mbar, further providing said aerosol with mean particle sizes predominantly from about 1 to about 5 μm, and thereby resulting in the delivery of said inhalable corticosteroid predominantly into the target area of the small airways of the lower lungs, wherein said system further enables such delivery to be achieved in less than 14 minutes, preferably less than 10 minutes and most preferably in from 6 to 8 minutes, and wherein said inhalation system further comprises a pre-programmable therapeutic protocol card for patient individualization of the treatment protocol and for the assurance of compliance with such protocol.
Yet another aspect of the current invention is a method for treatment of severe, oral corticosteroid-dependent asthma and other oral corticosteroid-dependent respiratory diseases with a nebulized inhalable corticosteroid drug selected from the group consisting of budenoside, fluticasone, beclomethasone dipropionate, mometasone furoate, ciclesonide, flunisolide or triamcinolone acetonide wherein the clinical effect is reached with minimum efficacious amount of precisely targeted drug to the small airways of the lungs and with eliminated or greatly diminished systemic and local extrathoracic or oropharyngeal side effects.
Still yet another aspect of the current invention is a method for treatment of severe, oral corticosteroid-dependent asthma by using a drug and device combination system for inhalation of nebulized budenoside, delivered into the target area of the lower lungs using an electronically controlled inhalation system, optionally comprising a jet nebulizer, and optionally enabling the application of an overpressure from above zero, such as 0.1 mbar, up to 40 mbar during inhalation wherein the concentration of budesonide in the aerosolizable drug composition is from about 0.1 to 2 mg/ml, preferably from 0.25 to about 1 mg/ml, with the total dose of budesonide not exceeding about 4 mg, and with the resulting deposition of said budenoside into the target area of the lower lungs being at least 0.2 mg or more, achieved in less than 14 minutes, preferably in from 6 to 10 minutes.
Still another aspect of the current invention is a method for treatment of severe, oral corticosteroid-dependent asthma by providing an inhalation system for individualization of the treatment wherein said inhalation system comprises a pre-programmable inhalation volume, flow rate and overpressure, and a compliance monitoring system which allows the patient and the doctor to see and control the adherence of the patient to the treatment protocol including a date, onset and duration of each single inhalation treatment, timing of inhalation, such as for example, morning or evening, inhaled dose per day, chosen inhalation volume setting and changes thereof, number of breaths taken, data on whether each single inhalation treatment was finished or interrupted, missed treatments and other therapeutic parameters, wherein such means are or may be any storage media, a smart card, a chip or a wireless communication connection that permits evaluation of the treatment during and after the end of a treatment period.
Yet another aspect of the current invention is the drug and device combination system of the invention for the treatment of inflammatory lung diseases that are oral corticosteroid-dependent, namely, severe asthma, chronic obstructive pulmonary disease (COPD), cystic fibrosis (CF), sarcoidosis, chronic bronchitis, emphysema, pulmonary fibrosis, bronchiectasis, cilliary dyskinesia and other respiratory diseases.
Still yet another aspect of the current invention is a drug and device combination system for use in a method for the treatment of a patient suffering from oral corticosteroid-dependent asthma or another respiratory disease requiring a treatment with orally administered steroids, said combination comprising an inhalable corticosteroid formulation and an electronically controlled inhalation device, wherein said inhalable corticosteroid is administered to the patient as an aerosol predominantly into the small airways of the lower lungs of the patient; wherein said inhalation device is adapted to generate said aerosol to have mean particle sizes from about 1 μm to about 5 μm at a controlled flow rate preset to be from 100 ml to 400 ml/second, using a bolus technique; wherein said aerosol is administered to the small airways of the lungs in two or three phases wherein a first phase is optional and consists of administering particle-free air, wherein said first phase is followed by a second phase consisting of administration of the aerosol comprising the corticosteroid, and wherein said second phase is followed by a third phase consisting of administration of particle-free air; and wherein such administration of the inhalable corticosteroid formulation results in complete or partial weaning of the patient from the orally administered corticosteroids, and clinically meaningful increase of the FEV1-values of the patient.
Definitions
As used herein:
“Drug” means an inhalable or oral corticosteroid, glucocorticoid or steroid, as defined below.
“Corticosteroid” means an anti-inflammatory steroid hormone glucocorticoid produced endogenously in the adrenal cortex of the brain. This hormone can be reproduced synthetically.
“Glucocorticoid” means an anti-inflammatory steroid hormone that influences carbohydrate metabolisms and binds to the glucocorticoid receptor which is present in almost every vertebrate animal cell.
“Inhalable corticosteroid” means a naturally or synthetically prepared corticosteroid that is suitable for delivery by inhalation. Exemplary inhalable corticosteroids are budesonide, fluticasone, beclomethasone dipropionate, mometasone furoate, ciclesonide, flunisolide, triamcinolone acetonide and any other inhalable corticosteroid currently available or becoming available in the future.
“Oral steroid” means any steroid that is suitable for oral or systemic treatment of asthma. Representative steroids are prednisone, prednisolone, methylprednisolone, dexamethasone or hydrocortisone.
“OCS” means an oral corticosteroid.
“Small airways”, “peripheral airways”, “deep lungs”, “lower lungs”, “small lungs” or “peripheral lungs” mean an area of the lungs primarily containing terminal bronchioles, respiratory bronchioles, alveolar ducts and alveolar sacs that are a primary site of asthmatic inflammation, narrowing and constriction. This area is a “target” area for the purposes of this application. Selective and targeted deposition of an inhalable corticosteroid preferably in the target area is eminently desirable and contributes to an efficacious treatment of severe and oral corticosteroid-dependent asthma.
“Large airways”, “upper lungs”, “central lungs” or “large lungs” mean an upper area of lungs containing larger bronchioles, bronchi and trachea. Large depositions of an inhalable corticosteroid in this area are undesirable as they are leading to development of adverse side effects.
“Oropharyngeal area” or “extrathoracic area” means a mouth, nose, throat, pharynx and larynx. Any deposition of the inhalable corticosteroid in these areas is undesirable and leads to development of severe adverse effect such as hoarseness, loss of voice, laryngitis and candidiasis. It is preferable that there is none or only a very small residual deposition, occurring primarily during expiration of the inhaled corticosteroid, in this region.
“One breath” means a period of time when a person inhales (inspires) and exhales during a regular breathing pattern that includes inhaling and exhaling.
“Inspiration time”, “inspiration period”, “inspiration phase” or “inhalation time/period/phase” means a fraction of one breath when a person inhales air or, in this instance, an aerosol or aerosolized drug, such as an aerosolized corticosteroid. “Inspiration”, “inspirational” or “inspiratory” and “inhalation” may be used synonymously. For purposes of this invention, the aerosolized corticosteroid is administered to an asthmatic patient during the inspiration time either without or, preferably, with an overpressure of from 0.1 to 40 mbar, to force the aerosol to the target area of the lower lungs with none or only a small amount of the drug deposition occurring in the extrathoracic area including the upper lungs and oropharyngeal area, using the protocol of the invention.
“Expiration time” means a fraction of one breath when a person exhales the air, nitric oxide or another metabolite from the lungs. For the purposes of this invention, it is preferable that the aerosolized drug is forced with a slight overpressure into the lower lungs during inspiration so that it remains in the lungs and is not exhaled during expiration time or that only a small portion of the inhaled drug is exhaled.
“Bolus technique” means transportation of the aerosol to a predefined region in the lungs by delivering an aerosol bolus during a predefined period representing a fraction of the inhalation time. The “bolus” is a large dose of the corticosteroid drug designed for rapid delivery. Thus, according to the bolus technique, drug-containing aerosol is not delivered throughout the complete inhalation time, but is emitted by the inhalation device only during a specifically selected fraction of said inhalation time. In other words, the inhalation time is divided into phases of variable duration. During a first optional phase of the inhalation time only aerosol-free air is administered. In a second phase, following the first (and sometimes referred to as the “nebulization phase” or “nebulization period”), the aerosol (i.e. the aerosolized drug) is delivered. The bout of aerosol delivered in said second phase represents the bolus. In a third phase, following the second phase, again aerosol-free air is administered to “push” the aerosol further down into the lungs and “clean” the upper lungs from aerosol, in order to reduce sedimentation of drug particles in the upper airways and decrease removal of the drug particles in the exhalation period.
“Filling dose” means the amount of a solution or suspension containing the appropriate dosage of the inhalable corticosteroid in an aqueous solvent which is filled into the nebulizer. Herein, the filling dose may contain budesonide (1 mg/2 ml or 0.5 mg/2 ml) or another inhalable corticosteroid in an appropriate dosage in, for example, about 2 ml of solvent.
“ECJN” means electronically controlled jet nebulizer.
“ECJN-Bud” means electronically controlled jet nebulizer filled with an appropriate dose of budesonide.
“CN” means a conventional jet nebulizer. Typically, a conventional nebulizer does not provide for a controlled, preset, or predefined inspiratory or inspirational flow rate or inhalation volume, and is particularly not suitable for or capable of delivering an aerosol using the bolus technique.
“CN-Bud” means a conventional jet nebulizer filled with an appropriate dose of budesonide.
“FEV1” or “FEV1” means forced expiratory volume in one second either in liter or milliliter. FEV1% value is the ratio of an individual's FEV1 value to same individual's forced vital capacity value (FVC). Depending on a person's height, weight, age and sex, normal healthy FEV1 values range between about 3 and 5 liter.
“FEV1% of predicted” means FEV1 value(s) expressed as a percentage based on the predicted average FEV1 of persons having similar parameters, such as height, age, weight and sex. Such percentages are interchangeably called “FEV1% of predicted”, “FEV1 (% of predicted)” or “FEV1 (% of pred.)”. Healthy persons usually exhibit ˜80-120% of FEV1 predicted, while patients suffering from respiratory diseases often achieve lower values. In this regard, FEV1% of predicted values are used as a means to evaluate the severity grade of a patient's lung disease, such as asthma. The FEV1% of predicted values are not to be mistaken with the “FEV1%” value which is the ratio of an individual's FEV1 value to same individual's forced vital capacity value (FVC). For the purpose of this application, the FEV1% predicted is as defined herein above, regardless whether in some other English speaking area, such definition might differ.
“VC” means vital capacity and is defined as the volume of gas that can be expelled from the lungs from a position of full inspiration, with no limit to duration of said inspiration.
“IC” means inspiratory capacity and is defined as the maximum volume of gas that can be taken into the lungs in a full inhalation after a normal, comfortable exhalation. Usually, IC-measurements are subject to larger fluctuations than FEV1 measurements, although both parameters are related lung-function parameters. Therefore, the preset inhalation volume used for the operation of the device according to this invention is chosen according to empirical data which are based on the patient's FEV1% of predicted (i.e. his/her asthma severity grade) and his/her FEV1 value, rather than being based on actual measurements of his/her IC.
“Aerosol” means a system having at least two phases, of which the continuous phase is gaseous and comprises a dispersed liquid phase in the form of small liquid droplets. Optionally, said liquid phase may itself represent a liquid solution, dispersion, suspension, or emulsion. Typically, the aerosol contains a drug that can be defined also as an active pharmaceutical ingredient, active compound or pharmaceutical and is for the purpose of this application, one of the named corticosteroids. Such aerosol is generated by, for example, a nebulizer from a liquid formulation in which the drug is dissolved, dispersed or suspended in a liquid, typically aqueous carrier. Herein, the terms “nebulized” and “aerosolized” are use synonymously.
“Particle-free air” means the air that does not contain any aerosolized drug. It is typically delivered before and/or after a bolus of the aerosolized drug when applying the bolus technique.
“Overpressure inhalation” means inhalation with actively provided air or aerosol that has a predefined flow rate and a predefined volume (ergo duration). Overpressure inhalation is typically applied during inspiration phase when the patient adjusts to the preset inspiratory flow rate as controlled by the device. If the patient's conditions, such as inflammation or constriction, result in a low inspiration volume, an overpressure of up to 40 mbar is applied during the inhalation phase to reduce the patient's inspiratory effort. Consequently, due to such overpressure, the patient is able to inspire a larger inhalation volume with a slower inspiration flow rate compared to a spontaneous inhalation. The minimum overpressure is slightly above zero, for example 0.1 mbar.
“Symptom exacerbation” means generally worsening of symptoms or conditions of a disease assessed by adverse effects.
“Asthma exacerbation” means worsening of asthma symptoms, often triggered by viral infections, and manifested through airway tightening, increased need for beta-agonists, and sometimes hospitalization. When the asthma exacerbation occurs, treatment is necessary to prevent a medical emergency, and such treatment may consist of administration of beta-agonists, steroids or antibiotics and, occasionally, also in oxygen treatment. Asthma instability due to external stimuli, allergies, smog, high altitude, etc., may be other triggers for asthma exacerbation.
“Asthma instability” means a state of the patient with asthma that is not stabilized with oral, intravenous, inhalable or otherwise administered corticosteroids or other drugs. Asthma instability can be determined and measured by asthma symptom scores, morning and evening peak expiration flow (PEF), average number of salbutamol (or another bronchodilator) puffs per day, nocturnal awakenings, Asthma Quality of Life Questionnaire (AQLQ) scores, number of days of hospitalization, and absenteeism from work or school.
“Weaning” means removing or at least reducing the need for oral corticosteroid administration and treatment. Weaning may be either instantaneous where the oral drug is removed immediately or continuous where the amount of the oral drug is slowly decreased by tapering. After weaning, the drug dose required to control a disease or a symptom is smaller than the initially required dose. Partial weaning is defined as a dose reduction to ≦50% of the initial dose (also called baseline dose). Thus, by definition, the group of partially weaned patients includes the group of completely weaned patients (also called fully weaned patients) whose dose could be reduced to zero.
“Electronically controlled jet nebulizer” means an electronically controlled jet inhalation system comprising a portable, table-top inhalation device comprising a jet nebulizer unit equipped with a mouthpiece and the container for holding the drug solution for aerosolization, said nebulizing unit further connected to a case holding the compressor, airflow pump and electronic control unit including a display, navigation and therapeutic information card for individualization of parameters for a therapeutic treatment protocol.
“Therapeutic protocol card”, “therapeutic information card”, or “individualized patient's treatment protocol card”, means an information holding card that is a part of the device where the individualized parameters for patient's treatment are entered and logged in order to provide this information to the electronic control unit that controls the progress of each treatment. In addition, the therapeutic protocol card serves as a data storage means during the whole treatment period which allows for compliance monitoring. Therapeutic parameters stored for compliance monitoring include for example the date, onset and duration of each single inhalation treatment, timing of inhalation (morning vs. evening), inhaled dose per day, the chosen inhalation volume setting and changes thereof, the number of breaths taken, data on whether each single inhalation treatment was finished successfully or was interrupted, whether the patient inhaled too fast, whether the pressure at the mouthpiece was too high or too low, whether treatments were missed (usually hi-daily inhalation treatments), but also more technical information on the operation of the device such as error codes for certain events like “compressor damaged” or “wrong tubing attached”.
“Clinically meaningful improvement” means improvement in patient conditions due to a drug and device combination treatment of the invention that does not occur when the same patient is treated with the same corticosteroid and dosage using a conventional nebulizer and previously used administration methods.
“MCID” means minimally clinically important difference.
“MMAD” means mass median aerodynamic diameter.
“Substantially” means at least 40% but is preferably more than 50%.
“Predominantly” means at least 50% but is preferably at least and above 75%.
This invention concerns generally a drug and device combination system used in a method for inhalation therapy for treatment of severe and oral corticosteroid-dependent asthma and other respiratory diseases requiring a treatment with orally administered steroids. The inhalation therapy according to the invention results in the following benefits: complete weaning of more than 50% of all patients from oral corticosteroids; partial weaning to ≦50% of the initial oral corticosteroid dose in 80% of all patients treated with orally administered corticosteroid medication; substantial improvement in forced expiratory volume in one second (FEV1) achieved after 18 weeks of treatment; significant improvement of asthma Quality of Life measured by the Asthma Quality of Life Questionnaire(AQLQ); reduction of exacerbation of asthma symptoms; decrease in length and frequency of hospitalization of patients due to asthma episodes; and expectation of all these benefits to be achieved without any or with highly diminished secondary adversary reactions.
The Method
The method utilizes devices allowing the control and individualization of the flow rate and volume of the aerosol, optionally together with the application of an overpressure for severely asthmatic patients with a compromised breathing pattern. In this regard, the method comprises narrowly defined and controlled administration of the inhalable corticosteroid by a flow rate and volume regulated inhalation wherein the drug is administered predominantly into a target area of the lungs, in particular the small airways of the lungs, comprising terminal and respiratory bronchioles and alveolar ducts and sacs, by using a system comprising an inhalable corticosteroid drug and device combination.
The System
The system comprises a combination of an inhalable corticosteroid drug and an electronically controlled nebulizer device, such as a jet nebulizer, that regulates the aerosol's mean particle sizes as well as the flow rate and volume. The combination system permits a precise and fine tuning of the delivery of the inhalable drug into the lungs at an optimized flow rate and in an optimized volume to assure maximal homogeneous and reproducible peripheral deposition into the lung target area, with a minimal or nil deposition of the inhalable drug in the upper lungs, oropharyngeal or extrathoracic area.
The Inhalation Therapy
The inhalation therapy is individualized and programmable into a treatment protocol for the therapy design based on a patient's individual health conditions, as estimated from his/her FEV1 and FEV1% of predicted values. Depending on these values an appropriate inhalable corticosteroid and its required dose is chosen as well as an inhalation volume which will be tolerated by the individual patient. See further details on patient individualization below.
The Treatment Protocol
The individual treatment protocol is logged into each patient's therapeutic protocol card that is a part of the device. The protocol card is also used for a follow-up monitoring of compliance or non-compliance with such protocol. The individualized treatment protocol card comprises all relevant therapeutic parameters such as for example the date, onset and duration of each single inhalation treatment, the chosen inhalation volume setting and changes thereof, the number of breaths taken, data on whether each single inhalation treatment was finished successfully or was interrupted, whether the patient inhaled too fast, whether the pressure at the mouthpiece was too high or too low, whether treatments were missed, particularly with regard to bi-daily inhalation treatments, but also more technical information on the operation of the device such as error codes for certain events like “compressor damaged” or “wrong tubing attached”.
The Device
The device of the invention is an electronically controlled inhalation system, such as a jet nebulizing system, modified to accommodate individualization of the treatment protocol and other features required for maximization of the treatment efficacy, accuracy, safety and reproducibility. The device of the invention automatically terminates therapy if and when the required dose is delivered by the required number of breaths and, therefore, overdosing is not possible. The safety of the device is further assured by the fact that due to its individual programming, wrong settings are not possible and every single inhalation volume delivers the same dose to the lungs. The electronically controlled inhalation system is seen in
The Safety and Efficacy
The system, including a method and a treatment protocol, is safe, efficacious, reproducible, controllable, well tolerated by patients and individually programmable to assure a treatment safety and compliance. When the treatment protocol is followed, it results in very few side effects, in a very low number of asthma exacerbation episodes, and it improves the Quality of Life of patients and reduces occurrences and length of hospitalizations. The device's capability to control and regulate flow rate and inhalation volume regulating assures dose reproducibility and maximized, homogeneous delivery of the inhalable drug directly to the target areas of the lower lungs. Furthermore, this decreases the deposition of inhalable corticosteroids in the upper lungs and the oropharyngeal area and thereby reduces the drug dose requirement, drug waste and undesirable side effects.
Improvements in Asthma and Respiratory Diseases
The method of the invention results in complete or partial weaning of a patient from orally administered steroids and in an unexpectedly large improvement of pulmonary function, improvement in Quality of Life in asthmatic patients, unexpected and substantial reduction of symptoms exacerbations, reduction in frequency and lengths of hospitalizations and in recovery of endogenous cortisol production.
The Inhalable Corticosteroid Drugs
The inhalable corticosteroid drug is selected from the group consisting of budesonide, fluticasone, beclomethasone dipropionate, mometasone furoate, ciclesonide, flunisolide and triamcinolone acetonide. It is intended that also included are any other inhalable corticosteroids that are or may be currently available, may be in development or may become available in the future.
Budesonide as a Representative Inhalable Corticosteroid
Budesonide was selected as a representative inhalable corticosteroid in the following clinical studies performed in order to develop an efficacious drug and device combination system for weaning patients from orally administered corticosteroids. The system comprises a drug and device combination, a method and a protocol for treatment of severe asthma and other oral corticosteroid-dependent respiratory diseases. Aim of these studies was to provide a system that would result in a safe and well tolerated complete weaning of patients from the orally administered steroids or in a safe and well tolerated partial weaning to at least 50%, preferably less than 50% of the initial oral corticosteroid dose, for those patients still requiring a concomitant oral administration of corticosteroid. As described below, when the protocol of the invention is followed, the administration of budesonide (1 mg or 0.5 mg) in a twice a day regimen was sufficient to achieve these aims.
With exception of dose adjustments, budesonide may be replaced with every other inhalable corticosteroid such as fluticasone, beclomethasone dipropionate, mometasone furoate, ciclesonide, flunisolide, triamcinolone acetonide and any other corticosteroid currently available or becoming available in the future. All these corticosteroids are suitable to be used in the system and the method of the invention.
For clinical studies, the budesonide was administered to severely asthmatic patients with oral corticosteroid-dependency who were until then treated with oral corticosteroids. The clinical studies were multi-center, double-blind, randomized and placebo-controlled. Budesonide was prepared and added to the nebulizer in a 2 ml filling dose. 199 patients with severe asthma classified as Gina V stage, between 18 and 65 years old, treated regularly with oral corticosteroids, were subject of this clinical trial of which 80 patients were treated with budesonide full dose (ECJN-Bud/1 mg), 39 patients were treated with budesonide half dose (ECJN-Bud/0.5 mg), 40 patients were controls treated with placebo (2 ml saline), with all three above treatments using the electronically controlled jet nebulizer, and 40 patients were treated with budesonide full dose using a conventional PARI® LC nebulizer (CN-Bud/1 mg). All subjects were patients suffering from severe asthma treated prior to the clinical trial for at least 6 months with oral corticosteroids in dosages from 5 mg to 40 mg per day.
Budesonide was administered twice daily (BID) in 1 mg/2 ml or 0.5 mg/2 ml filling doses (based on saline solution) administered either with the electronically controlled jet nebulizer (ECJN-Bud) or in only the 1 mg/2 ml filling dose with the conventional PARI® nebulizer (CN-Bud). Saline (0.9%; 2 ml) was used as a control placebo medication and administered as 2 ml solution twice a day to a control group of patients with the electronically controlled jet nebulizer (ECJN-Placebo). The filing dose (2 ml) of the budesonide solution containing either 1 mg or 0.5 mg of budesonide was placed into the container of the nebulizer. The solution was administered as an aerosol having a mean particle size predominantly in the range from 1 to about 5 μm, preferably between 3 and 4 μm and most preferably about 3.8 μm (MMAD) using the electronically controlled jet nebulizer for a flow rate and volume controlled inhalation or the conventional PARI nebulizer (CN-Bud) without such control. The clinical trial lasted 18 weeks including the therapy and oral corticosteroid tapering, followed by post clinical trial monitoring.
In terms of weaning patients from the oral corticosteroids, results of this clinical study shows that there was complete weaning from orally administered corticosteroids in more than 50% of all treated patients and there was partial weaning to ≦50% of the initial oral corticosteroid dose in about 80% of all treated patients. In other words, following the treatment protocol with the full budesonide dose (ECJN-Bud/1 mg), more than 50% of all patients were completely weaned from oral corticosteroids after 18 weeks of treatment. Additionally, 80% of all treated patients were weaned to at least 50% or less of their initial daily dose of oral corticosteroid.
Complete Weaning from Oral Corticosteroids in Asthmatic Patients
Patients diagnosed with asthma, particularly with severe and oral corticosteroid-dependent asthma requiring treatment with orally administered corticosteroid are completely weaned from oral corticosteroids in more than 50% of all cases, specifically 56.3%, when subjected to inhalation therapy using the drug and device combination system and a method according to the invention. Results are seen in
As seen from
Additionally, improvements in overall physical conditions and functions of the lungs, such as improvement of FEV1, AQLQ, exacerbation of asthma, number and length of hospitalization, and side effects, as further described below, were observed in subjects fully weaned from oral corticosteroids.
Partial Weaning from Oral Corticosteroids in Asthmatic Patient
Patients diagnosed with severe and oral corticosteroid-dependent asthma requiring a treatment with orally administered corticosteroids show a reduction by at least 50% or more in their initial daily dose of oral corticosteroids in about 80% of all cases, when subjected to inhalation therapy using the drug and device combination system according to the invention. These results show that the dosage of oral corticosteroids which is still required by such partially weaned patients that is concomitant to the inhalation therapy according to the invention, is smaller or equal to 50% of their initial dose. Note that by definition the group of partially weaned patients includes the group of completely weaned patients.
As seen in
These results were further analyzed for the subgroup of subjects initially treated with an oral corticosteroid dose larger than 10 mg/day. The results are seen in
Improvements in overall physical conditions and functions of the lungs, such as improvement of FEV1, AQLQ, exacerbation of asthma, number and length of hospitalization, and side effects, as described below, were observed in subjects partially weaned from oral corticosteroids.
FEV1 Improvement in Treated Asthmatic Patients
Functionality of the lungs, determined by forced expiratory volume in one second (FEV1), is improved significantly with about 17% increase observed for the median value FEV1% of predicted after 18 weeks of treatment with full dose (1 mg) of budesonide, using the drug and device combination system of the invention.
Table 3 presents the results of the FEV1 improvement depicted in
Results seen in
Quality of Life Improvement in Treated Asthmatic Patients
Following the treatment with drug and device combination system of the invention, Quality of Life in asthmatic patients, determined by Asthmatic Quality of Life Questionnaire (AQLQ) is improved significantly by 0.83 score points which is clearly above the minimally clinically important difference (MCID) of 0.5 points.
Quality of Life (QoL) of subjects treated according to the invention was assessed via the validated Mini Asthma Quality of Life Questionnaire (MiniAQLQ), which focuses on asthma symptoms that affect subject's Quality of Life. It contains 15 questions which are divided into different domains, representing different potential impairments patients with asthma typically report (i.e., symptoms, activity limitation, emotional function and environmental stimuli).
When the AQLQ total score was determined in subjects with complete weaning from OCS treated with full dose of budesonide and compared to placebo, there was a significant (P=0.0352) improvement in Quality of Life in budesonide treated patients. Such improvement was expressed as a total score above or under the minimal clinically important difference (MCID) set to be 0.5. As seen in
Based on the results above, clearly the Quality of Life in severe asthma subjects treated with 1 mg of inhalable budesonide according to the invention was improved and these subjects experienced such clinically meaningful improvements in QoL even and particularly when reducing oral corticosteroids and replacing them with the improved budesonide inhalation according to the invention. QoL improvement also included improved and increased FEV1 and reduced usage of emergency medication, such as for example salbutamol.
Exacerbation of Asthma Symptom in Treated Subjects
The occurrence of exacerbations of asthmatic conditions is reduced to 7.5% and 7.7% of all cases, respectively, for the subjects treated with full and half dose of budesonide (ECJN-Bud/1 and 0.5 mg) compared to 17.5% of all subjects experiencing exacerbations in the placebo control group and even 22.5% in the group treated with the conventional nebulizer (CN-Bud/1 mg) as seen in
The results of the exacerbation study are shown in more detail in Table 4.
Moreover, the difference in exacerbation rate is even more evident when the more severely impaired subgroup of patients receiving an initial oral corticosteroid dose larger than 10 mg/day and up to 40 mg/day. In this subgroup, only 11.8% of subjects treated with the full dose of budesonide (1 mg) and only 14.3% of subjects treated with the half dose (0.5 mg) experienced at least one exacerbation, compared to 44.4% in the placebo group or 30.0% in the CN-Bud/1 mg group. The latter subjects, in particular, cannot be weaned safely from OCS.
The subgroup of patients initially requiring 5 to 10 mg/day of oral corticosteroids also showed lower numbers of exacerbations in the ECJN-Bud/1 mg and the ECJN-Bud/0.5 mg group (6.3% experiencing at least one exacerbation) compared to 9.7% of exacerbations in the placebo group and 20% exacerbation in the CN-Bud/1 mg group.
Hospitalization in Treated Asthmatic Patients
Severe oral corticosteroid-dependent asthma often results in asthma exacerbations requiring hospitalization and urgent care. Treatment of the asthma patients with the system and method of the invention results in pronounced reduction in asthma exacerbation episodes and fewer hospitalizations. Patients with oral corticosteroid-dependent asthma treated with the full dose of 1 mg of inhalable budesonide according to the invention were followed for 24 weeks and their hospitalizations were recorded. Results are seen in
Table 5 shows the number of days of hospitalization for each treatment group. Seven subjects out of the total 198 studied subjects reported hospitalizations due to asthma. The numbers of days in hospital ranged between 5 and 17.
Four subjects (10%) from the placebo group required between 9 and 17 days of hospitalization. In comparison, only one subject in each group treated with budesonide required hospitalization of 5 days; i.e. percentagewise, only 1.3% of subjects from the ECJN-Bud/1 mg group and 2.6% and 2.5% subjects of the ECJN-Bud/0.5 mg and the CN-Bud/1 mg groups, respectively. These results clearly show the advantages of treatment of patients with severe oral corticosteroid-dependent asthma achieved with the method and drug and device combination system of the invention.
Reduction in Bronchodilators Use
Bronchospasm, one of the severe asthma exacerbation symptoms, is typically treated with bronchodilators, of which the most preferably used is salbutamol. Salbutamol also known as albuterol belongs to the family of drugs known as adrenergic bronchodilators used to open up the bronchial tubes passages) in the lungs during bronchospasm caused by asthma.
Decrease or Elimination of Secondary Side Effects in Treated Asthmatic Patients
Treatment of severe oral corticosteroid-dependent asthma according to the invention has also an effect on the occurrence and severity of side effects typically observed with inhalable corticosteroids. Typically, when the corticosteroid is delivered by inhalation, a certain portion of the corticosteroid is deposited in oropharyngeal and/or extrathoracic area including mouth, nose, throat, pharynx and larynx. Any deposition of the inhalable corticosteroid in these areas is undesirable and leads to development of adverse effect such as hoarseness, dysphonia, loss of voice, laryngitis and candidiasis. For these reasons, it is preferable that there is no or only a very small residual deposition in the mouth, nose, throat, pharynx and larynx as well as in extrathoracic areas including the larger bronchiole, bronchi and trachea. Despite the higher efficacy of the treatment according to the invention as outlined above, said treatment does not result in any increase of such undesirable side effects. No pharyngeal candidiasis, no pneumonia, no oropharyngeal pain, no dysphonia, hoarseness, and only minor and negligible oral candidiasis in the mouth of only one patient and laryngitis were observed.
Table 6 summarizes results of side effects in the four groups investigated.
As seen in Table 6, there was no relevant increase in the side effects typically associated with inhalation of high doses of corticosteroids in the ECJN-Bud/1.0 mg group. When dysphonia, oropharyngeal pain, oral candidiasis and oropharyngeal candidiasis were investigated vis-à-vis each treatment group, only one patient reported presence of oral candidiasis in the ECJN-Bud/1 mg group with no other side effects being observed, whereas in the control group one case of pharyngeal candidiasis, one case of oropharyngeal pain and one case of dysphonia were observed. This further confirms safety, tolerability and effectiveness of the instant method and system for treatment of severe oral corticosteroid-dependent asthma.
Serum Cortisol Levels
As discussed above, severe asthma treated with steroids may lead to suppression of endogenous production of hydrocortisone (cortisol). As a consequence, when the oral administration of corticosteroids is stopped or decreased too rapidly, a life-threatening acute adrenal crisis caused by insufficient levels of cortisol may develop because the adrenal glands of the patient are unable to produce their own hormones fast enough in response to any stress situation.
To determine if the replacement of oral corticosteroids with instant inhalable corticosteroids affects the endogenous production of cortisol, levels of cortisol in plasma of studied subjects were determined. The results for the endogenous serum cortisol levels indicate that severe asthma patients of all four studied groups entered the study with a suppression of their HPA axis and that such HPA axis would at least partially recover after the inhalation therapy of the invention. These results would further indicate that the corticosteroids delivered by inhalation are advantageous for the patient when compared to orally administered corticosteroids as a major portion of the inhaled corticosteroid would be deposited in the small airways of the lungs, with only a small portion of the dose being transported to the blood stream and thus having much smaller suppressive effect on the HPA axis and on the resulting production of endogenous cortisol.
Efficacy of the Budesonide Inhalation
Serum levels of inhalable budesonide delivered according to the invention show dose response to the inhalation as well as, but to a lesser degree, to the used device.
For budesonide serum concentration analysis, blood was drawn in all four investigated groups either before inhalation or 30-60 minutes following inhalation at baseline (post-inhalation) and at week 18 (pre- and post-inhalation). Results are seen in
As seen in
Drug accumulation can occur if the dosing interval is shorter than the elimination half-life. The dosing interval for ECJN-Bud is roughly 12 hours (bi-daily) whereas the published elimination half-life for budesonide is 2.2-4.5 hours after IV or inhalation administration. Evaluation of the temporal trend of budesonide serum levels from baseline to week 18 indicates that budesonide did not accumulate in serum over the 18-week treatment period; i.e., baseline post-inhalation mean serum budesonide concentrations were not significantly different from week 18 post-inhalation levels (independent t-test, equal variance, α=0.5).
Drug and Device Combination System for Flow and Volume Regulated Inhalation
A complete or partial reduction in use of oral corticosteroids for treatment of severe, oral corticosteroids-dependent asthma or other respiratory diseases is achieved with a novel drug and device combination system that effectively controls the flow rate and inhalation volume of the inhalable corticosteroid into the patient's lungs and selectively deposits the inhalable drug in the target area, i.e., small airways of the peripheral lungs.
Drug and Device Combination System
Drug and device combination system of the invention comprises of an inhalable corticosteroid and of the electronically controlled inhalation device, such as a jet nebulizer. The drug is an inhalable corticosteroid. The device used in the above described studies with budesonide is a modified, manually triggered PARI LC® Star nebulizer that is enhanced with an electronic control unit. While the nebulizer part generates and delivers the corticosteroid containing aerosol, the electronic control unit assures the compliance with an optimal breathing maneuver programmed individually for each patient and logged and saved on an individual therapeutic protocol card inserted into the device. The electronic control unit further comprises preselected settings for the treatment protocol, such as personal volume and flow rate settings, number of breaths vis-à-vis delivered volume, a monitored compliance with the individual treatment protocol, delivery of the same dose during each treatment, automatic disconnection of the device in case of malfunction or overdosing, automatic conclusion of the therapy once the predetermined dose is inhaled.
The inhalable corticosteroids suitable for treatment of oral corticosteroid-dependent asthma or other respiratory disease needing oral corticosteroid treatment are naturally or synthetically prepared corticosteroids that are suitable for delivery by inhalation. Exemplary inhalable corticosteroids are budesonide, fluticasone, beclomethasone dipropionate, mometasone furoate, ciclesonide, flunisolide and triamcinolone acetonide. Also included in this group are any other inhalable corticosteroids that may be currently available, are currently in development or may become available in the future.
Inhalable Corticosteroids Dosing
While the representative corticosteroid budenoside was tested and found to be efficacious for treatment of severe oral corticosteroid-dependent asthma or another respiratory disease requiring treatment with oral corticosteroids when delivered in the daily dose of 1 or 2 mg/day, such dose may be adjusted to be from 0.2 to 0.8 mg delivered from 1 to 4 times a day, with maximum daily dose for inhalation not to exceed 3.2 mg/day. Preferable dose for treatment of severe asthma is from 0.5 to about 1 mg delivered twice a day (BID).
Inhalable fluticasone dose for treatment of patient with oral corticosteroid-dependent asthma or another respiratory disease requiring treatment with oral corticosteroids is from about 0.1 mg to about 1 mg delivered BID, with preferable dose 0.88 mg BID. The maximum daily dose should not exceed 2.5 mg, preferably should not be higher than 1.6 mg/day.
Inhalable flunisolide dose for treatment of patient with oral corticosteroid-dependent asthma or another respiratory disease requiring treatment with oral corticosteroids is from about 0.5 mg to about 1 mg delivered BID, with preferable dose 1 mg BID. The maximum daily dose not to exceed 3 mg, preferably not over 2 mg/day.
Inhalable triamcinolone acetonide dose for treatment of patient with oral corticosteroid-dependent asthma or another respiratory disease requiring treatment with oral corticosteroids is from about 200 μg to about 800 μg. Preferred inhalable dose delivered BID is from about 150 μg to about 300 μg. The maximum daily dose not to exceed 2000 μg, preferably not over 800 μg.
Inhalable beclomethasone dipropionate dose for treatment of patient with oral corticosteroid-dependent asthma or another respiratory disease requiring treatment with oral corticosteroids is from about 0.1 mg to about 0.8 mg delivered BID, with preferable dose 0.5 mg BID. The maximum daily dose not to exceed 2 mg, preferably not over 1 mg/day.
Inhalable mometasone dose for treatment of patient with oral corticosteroid-dependent asthma or another respiratory disease requiring treatment with oral corticosteroids is from about 0.1 mg to about 0.5 mg delivered BID, with preferable dose 0.25 mg BID. The maximum daily dose not to exceed 2 mg, preferably not over 0.5 mg/day.
Inhalable ciclesonide dose for treatment of patient with oral corticosteroid-dependent asthma or another respiratory disease requiring treatment with oral corticosteroids is from about 0.05 mg to about 0.6 mg delivered BID, preferably from 0.08 mg to 0.4 mg BID. The maximum daily dose not to exceed 2 mg, preferably not over 1 mg/day.
The Device Comprises a Nebulizer Unit and an Electronic Control Unit
The device of the invention comprises of three parts, namely of the nebulizer, the compressor, the airflow control pump and the electronic control unit including a pre-programmable therapeutic protocol card. The device is seen in
The nebulizer unit 12 of the device 10 is an appropriately set-up basic PARI® LC Star jet nebulizer designed for delivering the aerosolized inhalable corticosteroid into the target areas of the lungs in high dose in short inhalation time. However, any other type of nebulizer unit, such as other jet nebulizers, ultrasonic nebulizers, or vibrating mesh nebulizers can be coupled with the device 10. The PARI® LC Star jet nebulizer unit is a continuous nebulizer equipped with valve system having a high aerosol output of from about 0.20 to about 0.35 ml/min, typically about 0.23-0.25 ml/min. The nebulizer uses a breath-enhanced delivery and is able to predominantly (more than 75%) generate particles having substantially optimal mean particle size of between 1 and 5 μM, preferably about 3.0 to 4.0 μm, and most preferably about 3.8 μm (MMAD) with geometric standard deviation (GSD) of less than 2.5. The nebulizer has a container 20 with approximately 6 ml of total capacity and further comprises the mouthpiece 22 and a tube 24 connecting the nebulizer to the airflow control pump which provides the air flow to assist inspiration and for the control of flow rate and volume, and a tube 26 connecting the nebulizer to the compressor 28 for generating the drug aerosol. Both, the compressor and the airflow control pump are placed in the same case 16 that also holds the electronic control unit 14. The nebulizer is adjusted to minimize waste of the drug in extrathoracic space and to maximize the amount of the drug deposited in the small airways of the lungs and to deliver about 80% of the drug filling dose in the respirable range of particles smaller than 5 μm within a treatment duration of from about 10 to about 14 minutes.
The electronic control unit 14 comprises a means for controlling the breathing pattern of a patient, e.g. by providing a predefined inspiratory flow rate and a predefined inhalation volume. Moreover, it is configured to deliver an aerosol using the bolus technique as defined above.
The electronic control unit further includes a display 30. The display 30 provides a patient friendly therapy support (e.g., by displaying feedback messages when patient inhales too fast), has adjustable settings for patient-specific inhalation volume, flexible volume regulation, instructions for therapy, feedback on inhalation and complete information on unit progress.
Furthermore, the unit has a slit 34 where the therapeutic protocol card 32, containing individualized drug and treatment-specific information, is inserted for each individual patient. This therapeutic protocol card 32 stores logged drug data (e.g., type of drug, filling dose and required daily dose) and information on the individual patient (e.g., his/her most appropriate pre-set inhalation volume) required by the electronic control unit. It further records all therapy-related data for compliance monitoring as described below.
The drug-specific therapeutic protocol card 32 is an electronic chip card that is designed to transfer all relevant therapy parameters, such as the drug and dose-specific inhalation information to the electronic control unit, and that assures delivery of the inhalable corticosteroid in the right dosage to the target site of the lungs. These therapy parameters depend on the patient's conditions and required treatment.
The therapeutic protocol card provides information for a specific corticosteroid drug and its respective recommended dosage and desired deposition area in the lungs. Depending on individual subject's inspiration capacity (IC), a physician, nurse or a patient can select the personal inhalation volume. In a better, less variable alternative, the lung function of a patient is based on FEV1 determinations which then allow the selection of an appropriate inhalation volume to be pre-set for the individual patient, based on empirical data as seen exemplary in Table 7. In cooperation between physician and patient, an initial volume as high as is well tolerable for the patient will be chosen.
Of course, if the patient is able to tolerate an inhalation volume higher than 1400 ml, such higher volume will be selected, e.g., 1600, 1800 or 2000 ml. Typically, the inhalation volume will be from about 400 ml up to about 2000 ml. Based on each patient's specific inhalation volume, the electronic control unit then calculates the number of breaths necessary to inhale the required lung dose. The treatment automatically finishes when the complete lung dose has been inhaled (i.e., the calculated number of breaths being taken) and therefore, both under and over dosing can be prevented. The therapeutic protocol card in combination with the electronic control unit enables the patient at all times—even during one inhalation treatment—to choose a higher or lower volume if better tolerated; the device will then simply re-calculate the number of breaths (still) required for the complete administration of the required dose.
The therapeutic protocol card provides the information for an inhalation treatment on the drug (budesonide), the filling dose (1 mg/2 ml) and on the number of breaths needed to complete treatment when a certain flow rate and inhalation volume is selected. Representative information for setting up the individual inhalation volume, the resulting approximate number of breaths required to administer the complete dose and the approximate duration of one inhalation treatment is seen exemplary in Table 8. (For reasons of simplicity the ratio of inhalation and exhalation period is assumed to be 1:1. It is, however, acknowledged that for severely asthmatic patients said ratio can shift to even 0.4:1, thus potentially increasing the treatment duration.)
As seen from Table 8, when for example the inhalation volume is selected to be 400 ml, inhalation period 2 seconds, with a nebulization period of 1 second, then 273 breaths are needed to complete treatment and to deliver the complete 2 ml filling dose (equals 1 mg budesonide) to the lungs. If the inhalation volume is selected to be 1000 ml, the inhalation time is 5 seconds which favorably expands the nebulization period to 4 seconds; then only 68 breaths are necessary to completely deliver the whole dose.
All accumulated therapeutic data are saved on the therapeutic protocol card for compliance analysis, which is important for evaluation of efficacy of the treatment because doctors and patients can analyze the treatment protocol and change it as appropriate.
Therapeutic parameters stored for compliance analysis and monitoring include for example the date, onset and duration of each single inhalation treatment, timing of inhalation (morning vs. evening), inhaled dose per day, the chosen inhalation volume setting and changes thereof, the number of breaths taken, data on whether each single inhalation treatment was finished successfully or was interrupted, whether the patient inhaled too fast, whether the pressure at the mouthpiece was too high or too low, whether treatments were missed (usually bi-daily inhalation treatments), but also more technical information on the operation of the device such as error codes for certain events like “compressor damaged” or “wrong tubing attached”. Thus, inhalation therapy with the device of the invention can be specifically adapted based on the patient and his individual conditions. The device therefore provides the optimal solution for the therapeutic inhalation of aerosolized corticosteroids.
Flow Rate and Volume Regulated Inhalation
The drug and device combination system of the invention provides flow rate and volume regulated inhalation and thereby delivers the drug selectively to a target area of small airways of the lungs.
Pulmonary deposition studies investigated the extent and pattern of pulmonary deposition of the inhaled budesonide when the inhalation had a regulated flow rate and volume. Results seen in
Furthermore, as seen in
The method of the invention thus provides for drug targeting to the small airways of the lungs by flow rate and volume controlled inhalation and further by administering the aerosolized drug as a bolus. According to the bolus technique, the drug-containing aerosol is not delivered throughout the complete duration of the inhalation phase of a breathing maneuver. Rather, it is emitted from the inhalation device only during a specifically selected fraction of the inhalation phase. In other words, the inhalation time (or inspiration time) is subdivided into phases of variable duration. For example, during a first optional phase of the inhalation time, only aerosol-free air is delivered from the inhalation device. In a second phase, following the first phase and sometimes referred to as the nebulization phase or nebulization period, the aerosol (i.e. the aerosolized drug) is delivered; the aerosol delivered in this phase may represent the aerosol bolus. In a third phase, following the second phase, aerosol-free air is again delivered.
It has been found that the bolus technique can be used to transport the drug containing aerosol to a predefined region in the lungs. The shorter the duration of the first period for particle-free air the deeper the target area which will be reached by the subsequently administered aerosol bolus in the second period. Optionally, the duration of the first period can be zero. The third period of particle-free air results in “pushing” the aerosol bolus deeper into the lungs, thereby clearing the upper airways from aerosolized drug particles, and allowing the aerosol particles time to settle, which minimizes their undesired exhalation from the upper lungs and from the oropharyngeal area. Therefore, the duration of the third period which follows the aerosol bolus is typically far longer than the first period, if deeper deposition in the lungs is desired. In one specific embodiment of this invention, the duration of said third period is constant at 1 second while the first period was omitted, as is shown in the example of Table 8.
Inspiration of the bolus is typically achieved through the mouthpiece of the nebulizer. Expiration is typically done without the mouthpiece; this turned out to be more agreeable for most asthma patients.
Although the most favorite and preferable flow rate and volume is as set above, the severe conditions experienced by patients with oral corticosteroid-dependent asthma require that the inhalation volume be flexible depending on the pulmonary status of the patient and thus they often need to be individualized. The instant drug and device combination system including the method and therapeutic protocol permits such individualization as described earlier.
Based on the patient's individual pulmonary status, the individual patient's inhalation therapy is dependent on the inspiration volume said patient can handle and thus the number of breaths the patient must take in order to receive a certain required dose. More severely affected patients with low FEV1 typically take a higher number of breaths with a lower inhalation volume while patients with less severe asthma with higher FEV1 take a lower number of breaths with a higher inhalation volume. It has to be remembered that the drug is administered using an aerosol bolus technique; i.e. the nebulization period (when drug-containing aerosol is administered) is always a bit shorter than the inspiration period, as also shown exemplary in Table 8. This means that the drug-containing “nebulization volume” per breath is also slightly smaller than the preset inhalation volume. Consequently, the administered lung dose of the inhalable corticosteroid is calculated based on number of breaths multiplied by “nebulization volume” per breath.
Additionally, in many cases of severe asthma and lung obstruction, the method can be further enhanced by using inhalation with overpressure. The device and the method therefore further provide means to deliver the corticosteroid aerosol to the patient's lungs under mild overpressure from about 0.1 mbar to no higher than 40 mbar. Such overpressure allows the aerosol to be actively forced to the small alveoli and bronchioles of the airways without causing damage to the lungs and is typically achieved with the compressor and/or airflow control pump unit built into the device. Such unit may be optionally further equipped with a timer so that the overpressure period is limited strictly to the inspiration time. In some device configurations, the air flow (or aerosol flow) provided by the inhalation device is triggered by the onset of a patient's inspiration. Because the air flow (or aerosol flow) is then provided with an overpressure, the patient's breathing effort is reduced. Consequently, patients with severe asthma or with other respiratory diseases characterized by lungs obstructions are able to perform a deeper and slower breathing pattern, compared to spontaneous inhalation without overpressure.
During the inhalation, the airflow control pump and/or the compressor provides a slight overpressure to the aerosol (or particle-free air) to allow preferable deposition of the aerosolized drug into the small airways and prevent its removal during expiration. During expiration, the overpressure is not applied and the patient exhales normally, without any airflow or overpressure being applied.
When the patient inhales from the mouthpiece, the pressure sensor responds and starts the delivery of an air flow by providing a positive overpressure or opening of an inspiration valve. This overpressure, which can be measured at the mouthpiece during inhalation, is different from the pressure or from the pressurized air stream which is used by a jet nebulizer to aerosolize a liquid into an aerosol. The overpressure lasts for the entire inspiration time. When the inspiration time is preselected (via the pre-selected inhalation volume and flow rate), the overpressure is automatically stopped or shut off at the end of the inspiration time because the compressed air supply is interrupted by the device at this time. After a period allocated for exhaling, the process is repeated on and off for the entire period of a single treatment, preferably for less than 11 minutes.
When this method of delivery is selected, during the inspiration time the aerosolized corticosteroid is forced under the overpressure, and—in particular if the bolus technique is used into the lower lungs. When the overpressure is withdrawn and the patient exhales, the drug forced into the lower lungs is not easily displaced and remains there, resulting in substantially higher deposition of the drug in the peripheral lungs than would happen with a normal breathing without overpressure. During the exhalation time, the small amount of the drug that is exhaled is the one that was in the upper lungs at the last moment of the inspiration time. Some fraction of this small amount may be deposited in the upper lungs or oropharyngeal area but most of it is exhaled.
The device of the invention has a specified flow rate which may be selected between about 100 and 400 ml/sec, preferably 200 ml/sec, i.e. 12 L/min. In this regard, the device controls the flow rate. Once the patient triggers the system by beginning to inhale, the device provides said specified flow rate of preferably 12 L/min (±20%). The slight pressure drop at the mouthpiece caused by the onset of the patient's inspiration triggers the flow rate controlled air flow which in turn guides the patient's inhalation. The breathing pattern is followed by the electronic control unit of the inhalation device and may be displayed on the display as a display message. Any error in inhalation pattern or breach of the therapeutic protocol or non-compliance is noted. For example, an error message would be generated and optionally displayed when the patient would create a negative pressure of less than −10 mbar or when the patient would obstruct the mouthpiece with a pressure of >30 mbar. Due to comfort, most patients end up with a mild overpressure of >0 to 20 mbar. It is to be noted that not all patients inhale with an overpressure but most asthmatic patients use this feature for more comfortable breathing.
Therapeutic Protocol for Inhalable Corticosteroids
Treatment protocol for practicing the instant invention has several parts. First, the suitable corticosteroid is identified and the appropriate dosage for twice a day (BID) delivery is determined. Second, the setting for the inhalation device concerning the air flow rate and volume as well as the filing dose for the corticosteroid is determined. Third, the patient's lung function is evaluated by a physician or even the patient himself. However, it is preferable that at least before or for the initial treatment, the forced expiratory volume per one second (FEV1) of a patient is determined and severity of asthma or other respiratory disease is noted (e.g. by the FEV1% of predicted value) for determination of proper parameters for the therapeutic treatment protocol including the flow rate, inhalation volume, dosage and optionally the overpressure. Fourth, the data are entered on the therapeutic protocol card, and the inhalation device settings are either entered into the display on the electronic unit of the device or read directly from said therapeutic protocol card. Fifth, the corticosteroid filling dose is added to the nebulizer unit of the device. Sixth, the electronically controlled inhalation is initiated.
The appropriate corticosteroid is selected from the group identified above and the appropriate dosage for the selected corticosteroid is determined. Typically, such dosage will be from about 0.1 mg to about 4 mg, delivered by inhalation once to four times a day, preferably about 1 mg dosage per one dosing with twice a day delivery. Most preferred corticosteroids are budesonide and fluticasone.
The appropriate drug dosage is then prepared by dissolution of the required drug dose in an appropriate, preferably aqueous medium or supplied as a ready-to-use filling dose. The filling dose is placed into the container of the nebulizer unit just before the start of the inhalation treatment.
The flow rate is set to be slow between 100 and 400 ml per second, preferably about 200 ml per second. The volume of the air flowing through the inhalation device is preferably set high on between about 400 and about 2000 ml, more preferably between about 1000 ml and about 2000 ml, most preferred about 1400 ml. However, depending on an individual patient's lung function and the severity of his/her disease, a much smaller volume may be selected, such as from 400 ml to 1600 ml, or for example 1000 ml. Preferred particle sizes of the aerosol are based on the target area of the corticosteroid deposition. The target area of the deposition for treatment of severe asthma are the small airways of the peripheral lungs that are best reached with aerosols having mean particle sizes of not smaller than 1 μm and no larger than 5 μm, preferably between 3 and 4 μm, and such as about 3.8 μm (MMAD).
As described earlier, the total number of breaths needed for delivery of the complete dosage of the corticosteroid per one inhalation treatment is based on the severity grade of the patient's condition (established by his/her FEV1 and FEV1% of predicted values). The FEV1 of the patient is determined, typically using a spirometry, to estimate the patient's inspiration capacity (IC) and hence choose an appropriate inhalation volume based on empirical data, as shown exemplary in Table 7. The corresponding number of breaths required to inhale a complete dose using a given filling dose (such as 1 mg/2 ml) is then set by the therapeutic protocol card according to Table 8.
The inhalation volume and the resulting number of breaths required are stored on the therapeutic protocol card so that later on the patient himself can set up the parameters for inhalation, in particular the volume, based on his/her physical conditions and well-being at any time, even during one inhalation treatment.
After all parameters are determined and properly entered into the electronic control unit of the inhalation device (either manually or preferably by the insertion of the therapeutic protocol card having said parameters stored on), the inhalation treatment is initiated. It is a very simple process comprising the following steps. The nebulizer unit is connected to the electronic control unit of the inhalation device, drug is filled into the nebulizer container, the patient is set up with the mouthpiece of the nebulizer and the ON button on the device is pressed to start the inhalation treatment. The inspiratory air flow (or aerosol flow) is automatically switched off once the whole dose is delivered, i.e. the patient will notice that he/she cannot inhale through the mouthpiece anymore after delivery of the total dose. Due to the electronic control of the flow rate and volume as well as constant aerosol particle sizes, every inhalation treatment delivers the same amount of drug to the lower lungs under the same conditions. There is no over or under-dosing. The electronic control unit monitors the progress and compliance of the inhalation with the preset flow rate and inhalation volumes and issues a warning in case the inhalation is too slow or too fast or when some other parameter changes during the inhalation.
The whole device may additionally be provided and supplied as a kit comprising the complete device including the inhalation device and the therapeutic information card, as well as separately supplied corticosteroid(s) in individual ampoules.
The drug and device combination of the invention that is electronically controlled with regard to flow rate and inhalation volume overcomes many problems and errors observed with uncontrolled inhalation treatments.
Commonly observed errors made by the patients during an inhalation maneuver are that their breathing is too fast, their breathing is too shallow or their breathing is not coordinated. When the patient breathes too fast, the high inhalation flow rate results in extremely high drug deposition in the back of the throat and the larynx, with almost no drug deposition in the deep lungs. When the patient's breathing is too shallow, a shallow breath takes on only a small inhalation volume that cannot transport the aerosolized drug particles deep into the lungs thereby resulting in minimal deep lung deposition. When the breathing is not well coordinated, for example when the aerosol production and the inspiration phase of a patient are not in line, there is none or lesser deep lung deposition. Moreover, there are problems with non-compliance. Some patients only take the drug when asthmatic symptoms occur and not continuously in a controllable manner. Patients with a poor breathing maneuver seldom profit from the unregulated inhalation therapy, because they generally do not get a sufficient amount of the drug into the lower lungs. Since these patients also have more side effects caused by the high extrathoracic deposition, an abortion of and withdrawal from inhaled corticosteroid therapy is more likely.
All these problems are advantageously overcome with electronically controlled inhalation using the drug and device combination of the invention.
This application is a Continuation-in-Part of the U.S. patent application Ser. No. 13/147,761 filed on Oct. 19, 2011, now U.S. Pat. No. 8,668,901 based on the PCT application PCT/EP2010/051321 having the International Filing Date Feb. 3, 2010, and is Continuation-in-Part of the U.S. patent application Ser. No. 12/365,754 filed on Feb. 4, 2009 (ABN). The above patent applications are hereby incorporated herein by reference.
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6401710 | Scheuch et al. | Jun 2002 | B1 |
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Number | Date | Country | |
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20130037024 A1 | Feb 2013 | US |
Number | Date | Country | |
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Parent | 13147761 | US | |
Child | 13605451 | US | |
Parent | 12365754 | Feb 2009 | US |
Child | 13147761 | US |