For other uses, see Inhaler (disambiguation).
A metered-dose inhaler (MDI)
An inhaler (or puffer) is a medical device used for delivering medication into the body via the lungs. It is mainly used in the treatment of asthma and Chronic Obstructive Pulmonary Disease (COPD). Zanamivir (Relenza), used to treat influenza, must be administered via inhaler.
To reduce deposition in the mouth and throat, and to reduce the need for precise synchronization of the start of inhalation with actuation of the device, MDIs are sometimes used with a complementary spacer or holding chamber device.
Decongestant inhalers are popular over-the-counter remedies for nasal congestion in the upper respiratory tract.
Contents
- 1 Types
- 1.1 Metered-dose (MDI)
- 1.2 Dry powder (DPI)
- 1.3 Nebulizers
- 1.4 Nasal
- 1.5 Analgesic
- 2 Propellants
- 3 Manufacturers
- 4 See also
- 5 References
- 6 Further reading
- 7 External links
Types
Metered-dose (MDI)
The most common type of inhaler is the pressurized metered-dose inhaler (MDI). In MDIs, medication is typically stored in solution in a pressurized canister that contains a propellant, although it may also be a suspension.[1] The MDI canister is attached to a plastic, hand-operated actuator. On activation, the metered-dose inhaler releases a fixed dose of medication in aerosol form. The correct procedure for using an MDI is to first fully exhale, place the mouth-piece of the device into the mouth, and having just started to inhale at a moderate rate, depress the canister to release the medicine. The aerosolized medication is drawn into the lungs by continuing to inhale deeply before holding the breath for 10 seconds to allow the aerosol to settle onto the walls of the bronchittus and other airways of the lung. Some inhalers are made to act instantly in case of an asthma attack, and others are made to act later.
Dry powder (DPI)
Dry powder inhalers release a metered or device-measured dose of powdered medication that is inhaled through a DPI device.
Nebulizers
Nebulizers — supply the medication as an aerosol created from an aqueous formulation.
Nasal
Nasal inhalers contain decongestant drugs to relieve nasal congestion in the upper respiratory tract. The active ingredient in most decongestants is either pseudoephedrine or phenylephrine. Many are sold over-the-counter without a prescription.[1]
Analgesic
Penetro brand inhaler from mid 20th century Mexico, part of the permanent collection of the Museo del Objeto del Objeto.
In 1968, Robert Wexler of Abbott Laboratories developed the Analgizer, a disposable inhaler that allowed the self-administration of methoxyflurane vapor in air for analgesia.[2] The Analgizer consisted of a polyethylene cylinder 5 inches long and 1 inch in diameter with a 1 inch long mouthpiece. The device contained a rolled wick of polypropylene felt which held 15 milliliters of methoxyflurane.
Because of the simplicity of the Analgizer and the pharmacological characteristics of methoxyflurane, it was easy for patients to self-administer the drug and rapidly achieve a level of conscious analgesia which could be maintained and adjusted as necessary over a period of time lasting from a few minutes to several hours. The 15 milliliter supply of methoxyflurane would typically last for two to three hours, during which time the user would often be partly amnesic to the sense of pain; the device could be refilled if necessary.[3]
The Analgizer was found to be safe, effective, and simple to administer in obstetric patients during childbirth, as well as for patients with bone fractures and joint dislocations,[3] and for dressing changes on burn patients.[4] When used for labor analgesia, the Analgizer allows labor to progress normally and with no apparent adverse effect on Apgar scores.[3] All vital signs remain normal in obstetric patients, newborns, and injured patients.[3] The Analgizer was widely utilized for analgesia and sedation until the early 1970s, in a manner that foreshadowed the patient-controlled analgesia infusion pumps of today.[5][6][7][8] The Analgizer inhaler was withdrawn in 1974, but use of methoxyflurane as a sedative and analgesic continues in Australia and New Zealand in the form of the Penthrox inhaler.[9][10][11][12][13][14]
Propellants
In 2009, the FDA banned the use of inhalers that utilize chlorofluorocarbons (CFC) as propellants for hydrofluorocarbons (HFA) inhalers; HFA is not environmentally inert as a greenhouse gas but does not affect the ozone layer.[15] While some asthma sufferers and advocacy groups contend that the latter are not as effective,[16] published clinical studies indicate equivalent control of asthma is achieved with use of HFA inhalers.[17] Inhalers used to treat asthma contains dry powder spin inhalers and aerosoles containing suspending liquid medicament, but in both the cases the size of suspended particles or powder particles must be less than 5 micrometres so as to increase the surface area and deliver the drug to the inner most areas. Such a sufficiently small size of particles is necessary for dispersion and also for rapid action.
While the impact of CFC of inhalers on the ozone layer had been minuscule, the FDA in its interpretation of the Montreal Protocol mandated the switch in propellants.[15] Patients expressed concern about the high price of the HFA inhalers as there is no generic version, which had been available in the CFC inhalers for many years.[16] The elimination of generics from the market led to a price increase in inhalers that is expected to cost American consumers, insurances and the government about $8 billion by 2017.[15]
Manufacturers
The largest manufacturers of inhalers are Cipla, GlaxoSmithKline (makers of the Advair Discus, a DPI), Midascare Pharmaceuticals Pvt Ltd, Merck, AstraZeneca (makers of Pulmicort and Symbicort) and Boehringer-Ingelheim (makers of Atrovent, Combivent, and Spiriva). BI, GSK, Merck, and AstraZeneca manufacture the medication being delivered via inhaler. However, 3M Drug Delivery Systems does some of the finished product manufacturing, as they are one of the leaders of MDI canisters, metering valves and other components.
See also
- List of medical inhalants
- Decongestant
References
- ^ Hickey, A.J., ed. (2004). Pharmaceutical Inhalation Aerosol Technology (2nd ed.). NY: Marcel Dekker.
- ^ Wexler RE (1968). "Analgizer: Inhaler for supervised self-administration of inhalation anesthesia". Abbott Park, Illinois: Abbott Laboratories. Retrieved 2010-11-21.
- ^ a b c d Romagnoli A, Busque L, Power DJ (1970). "The "analgizer" in a general hospital: a preliminary report" (PDF). Canadian Journal of Anesthesia 17 (3): 275–8. doi:10.1007/BF03004607. PMID 5512851.
- ^ Packer KJ, Titel JH (1969). "Methoxyflurane analgesia for burns dressings: experience with the Analgizer (subscription required)". British Journal of Anaesthesia 41 (12): 1080–5. doi:10.1093/bja/41.12.1080. PMID 4903969.
- ^ Major V, Rosen M, Mushin WW (1966). "Methoxyflurane as an obstetric analgesic: a comparison with trichloroethylene". BMJ 2 (5529): 1554–61. doi:10.1136/bmj.2.5529.1554. PMC 1944957. PMID 5926260.
- ^ Dragon A, Goldstein I (1967). "Methoxyflurane: preliminary report on analgesic and mood modifying properties in dentistry (subscription required)". Journal of the American Dental Association 75 (5): 1176–81. PMID 5233333.
- ^ Firn S (1972). "Methoxyflurane analgesia for burns dressings and other painful ward procedures in children (subscription required)". British Journal of Anaesthesia 44 (5): 517–22. doi:10.1093/bja/44.5.517. PMID 5044082.
- ^ Josephson CA, Schwartz W (1974). "The Cardiff Inhaler and Penthrane. A method of sedation analgesia in routine dentistry". Journal of the Dental Association of South Africa 29 (2): 77–80. PMID 4534883.
- ^ Babl F, Barnett P, Palmer G, Oakley E, Davidson A (2007). "A pilot study of inhaled methoxyflurane for procedural analgesia in children (subscription required)". Pediatric Anesthesia 17 (2): 148–53. doi:10.1111/j.1460-9592.2006.02037.x. PMID 17238886.
- ^ Grindlay J, Babl FE (2009). "Efficacy and safety of methoxyflurane analgesia in the emergency department and prehospital setting". Emergency Medicine Australasia 21 (1): 4–11. doi:10.1111/j.1742-6723.2009.01153.x. PMID 19254307.
- ^ Babl FE, Jamison SR, Spicer M, Bernard S (2006). "Inhaled methoxyflurane as a prehospital analgesic in children (subscription required)". Emergency Medicine Australasia 18 (4): 404–10. doi:10.1111/j.1742-6723.2006.00874.x. PMID 16842312.
- ^ McLennan JV (2007). "Is methoxyflurane a suitable battlefield analgesic?" (PDF). Journal of the Royal Army Medical Corps 153 (2): 111–3. doi:10.1136/jramc-153-02-08. PMID 17896540.
- ^ Medical Developments International Pty. Ltd. (2009). "PENTHROX (methoxyflurane) Inhalation: Product Information" (PDF). Springvale, Victoria, Australia: Medical Developments International Limited. Retrieved 2010-11-21.
- ^ National Prescribing Service (2010). "Methoxyflurane (Penthrox) for analgesia (doctor's bag listing)" (PDF). NPS RADAR. Canberra, Australia: National Prescribing Service, Department of Health and Ageing. Retrieved 2010-11-21.
- ^ a b c Nick Baumann (July–August 2011). "Why You're Paying More to Breathe". Mother Jones.
- ^ a b "Asthma Group Concerned "Green" Inhalers May Not be as Effective | ksdk.com | St. Louis, MO". ksdk.com. Retrieved 2010-11-21.
- ^ Hendeles L, Colice GL, Meyer RJ (March 2007). "Withdrawal of albuterol inhalers containing chlorofluorocarbon propellants" (PDF). N. Engl. J. Med. 356 (13): 1344–51. doi:10.1056/NEJMra050380. PMID 17392304.
Further reading
- Patton J (February 1998). "Breathing life into protein drugs — Inhalation of therapeutic macromolecules is a feasible, natural, more people-friendly, delivery system". Nat. Biotechnol. 16 (2): 141–3. doi:10.1038/nbt0198-141. PMID 9487516.
External links
- Basics aspects of inhaled pharmaceutical aerosols
- Recent advances in spray medication technology
- Discrete simulation of powder dispersion in pharmaceutical aerosol inhalers
Cardiopulmonary therapy
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Diagnostic |
- Pulmonary function testing
- Polysomnography
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Disease |
- Asthma
- Bronchiectasis
- COPD
- Cystic fibrosis
- Tuberculosis
- Pneumonia
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Therapy |
- Hyperinflation therapy
- Pulmonary hygiene
- Mechanical ventilation
- Oxygen therapy
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See also |
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Routes of administration / Dosage forms
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Oral |
Digestive tract (enteral)
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Solids
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- Pill
- Tablet
- Capsule
- Pastille
- Time release technology
- Osmotic delivery system (OROS)
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Liquids
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- Decoction
- Elixir
- Electuary
- Emulsion
- Extended-release syrup
- Effervescent powder or tablet
- Herbal tea
- Hydrogel
- Molecular encapsulation
- Powder
- Softgel
- Solution
- Suspension
- Syrup
- Syrup Concentrate for dilution and/or addition of carbonated water
- Tincture
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Buccal (Sublabial) Sublingual
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Solids
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- Orally disintegrating tablet (ODT)
- Film
- Lollipop
- Sublingual drops
- Lozenges
- Effervescent buccal tablet
- Chewing gum
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Liquids
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- Mouthwash
- Toothpaste
- Ointment
- Oral spray
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Respiratory
tract
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Solids
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- Smoking device
- Dry powder inhaler (DPI)
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Liquids
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- Anaesthetic vaporizer
- Vaporizer
- Nebulizer
- metered-dose inhaler (MDI)
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Gas
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- Oxygen mask and Nasal cannula
- Oxygen concentrator
- Anaesthetic machine
- Relative analgesia machine
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Ophthalmic /
Otologic / Nasal |
- Nasal spray
- Ear drops
- Eye drops
- Ointment
- Hydrogel
- Nanosphere suspension
- Insufflation
- Mucoadhesive microdisc (microsphere tablet)
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Urogenital |
- Ointment
- Pessary (vaginal suppository)
- Vaginal ring
- Vaginal douche
- Intrauterine device (IUD)
- Extra-amniotic infusion
- Orally administered drug for Urinary Tract Infection (e.g. phenazoperidine)
- Intravesical infusion
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Rectal (enteral) |
- Ointment
- Suppository
- Enema
- Murphy drip
- Nutrient enema
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Dermal |
- Ointment
- Topical cream
- Topical gel
- Liniment
- Paste
- Film
- DMSO drug solution
- Electrophoretic dermal delivery system
- Hydrogel
- Liposomes
- Transfersome vesicles
- Cream
- Lotion
- Lip balm
- Medicated shampoo
- Dermal patch
- Transdermal patch
- Contact (rubbed into break in the skin)
- Transdermal spray
- Jet injector
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Injection /
Infusion
(into tissue/
blood)
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Skin
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- Intradermal
- Subcutaneous
- Transdermal implant
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Organs
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- Intracavernous
- Intravitreal
- Intra-articular injection
- Transscleral
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Central nervous system
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- Intracerebral
- Intrathecal
- Epidural
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Circulatory / Musculoskeletal
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- Intravenous
- Intracardiac
- Intramuscular
- Intraosseous
- Intraperitoneal
- Nanocell injection
- Patient-Controlled Analgesia pump
- PIC line
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