The present invention relates generally to lung surfactant compositions and methods for treating pulmonary diseases. The invention specifically discloses the use of biocompatible highly fluorinated compounds, including fluorocarbons in the treatment of various pulmonary conditions.
The native lung surfactant consists of a complex mixture of phospholipids, neutral lipids and proteins. The surfactant comprises roughly 90% lipids and 10% proteins with a lipid composition of 55% dipalmitoylphosphatidylcholine (DPPC), 25% phosphatidylcholine (PC), 12% phosphatidylglycerol (PG), 3.5% phosphatidylethanolamine (PE), sphingomyelin and phosphatidylinositol (PI).
The lung surfactant functions are to reduce the surface tension within the alveoli. It helps to mediate the transfer of oxygen and carbon dioxide, promotes alveolar expansion and covers the surface of the lung alveoli. Reduced surface tension permits the alveoli to be held open under low pressure. In addition, the lung surfactant supports alveolar expansion by varying the surface tension depending on alveolar size.
Surfactant supplements are presently used therapeutically when the lung surfactant present does not allow efficient respiratory function. Surfactant supplementation is commonly used to treat Respiratory Distress Syndrome (RDS), when surfactant deficiencies compromise pulmonary function. While RDS is primarily a disease of newborn infants, an adult form of the disease, Adult Respiratory Distress Syndrome (ARDS), has many characteristics in common with RDS, thus lending itself to similar therapies. More generally, there exist various forms of acute lung injuries that are related to a dysfunction of the pulmonary surfactant.
The primary etiology of RDS is attributed to insufficient amounts of pulmonary surfactant. Those at greatest risk are infants born before the 36th week of gestation having premature lung development. Neonates born at less than 28 weeks of gestation have a 60-80% chance of developing RDS. RDS is a life-threatening condition.
Adult respiratory distress occurs as a complication of numerous conditions, including shock-inducing trauma, infection, burn or direct lung damage. The pathology is observed histologically as diffuse damage to the alveolar wall, with hyaline membrane formation and capillary damage. Hyaline membrane formation, whether in ARDS or RDS, creates a barrier to gas exchange. Decreased oxygen delivery produces a loss of lung epithelium, resulting in decreased surfactant production and foci of collapsed alveoli. This can initiate a vicious cycle of hypoxia and lung damage.
In those pathologies wherein the native lung surfactant is deficient or not functional, molecules of DPPC are immobilized in the form of crystalline islets and cannot re-spread onto the alveolar surface, which can greatly impair the respiratory cycle.
Surfactant replacement therapy has recently been used either alone or in combination with ventilation therapy. Early work with surfactant replacements used preparations of human lung surfactant obtained from lung lavage.
The second generation of surfactant substitutes are purified preparations of bovine and porcine lung surfactant. Like human surfactant, bovine lung surfactant preparation is complex. Sources are few and availability is limited. Further, while the use of bovine lung surfactant in neonates does not present a problem immunologically, bovine surfactant applications in adults could immunologically sensitize patients to other bovine products. Moreover, the absence of risk of transmission of the Creutzfeld-Jakob disease remains to be proven.
Formulations of synthetic surfactants have also been proposed. For instance, EP 050 793 discloses a combination of hexadecanol and DPPC.
Ventilation with liquid fluorocarbons has been proposed in U.S. Pat. No. 5,853,003, and was shown to be safe, improve lung function and recruit lung volume in patients with severe respiratory distress (Greenspan et al., Biomedical Instrumentation and Technology (1999) 33:253-259; Leach et al., New England Journal of Medicine (1996) 335:761-767). The biocompatibility of fluorocarbons has been discussed (Riess, Chemical Reviews (2001) 101:2797-2919; Riess, Tetrahedron (2002) 58:4113-4131).
A Langmuir DPPC monolayer is accepted as a pulmonary surfactant model. Upon compression, a DPPC monolayer undergoes a phase transition from a fluid liquid-expended state to a crystalline liquid-condensed state. Crystalline islets are thus formed due to the high cohesive energy of the DPPC molecules. During expansion (in the course of a respiration cycle), the molecules of DPPC involved in crystalline islets do not respread rapidly enough on the alveoli surface. For that reason, DPPC alone cannot function as an effective lung surfactant.
The inventors have discovered that highly fluorinated compounds, and in particular fluorocarbons, in a liquid or gaseous form, make it possible to inhibit the liquid-expended to liquid-condensed transition, and therefore prevent the formation of crystalline islets when a Langmuir phospholipid monolayer is compressed.
On that basis, it is provided a method for improving the fluidity and/or spreadability of the native lung surfactant in a human or an animal in need of such treatment, wherein the human or animal is administered with a fluorocarbon composition.
The fluorocarbon composition may be in a liquid or gaseous form, and may be administered neat as an aerosol or vaporized.
A preferred highly fluorinated compound is a fluorocarbon such as perfluorooctylethane (PFOE) or bis(perfluorobutyl)ethene (F-44E). A still preferred fluorocarbon is a brominated fluorocarbon, and a still more preferred fluorocarbon is perfluorooctyl bromide (PFOB).
In a preferred embodiment, the fluorocarbon is administered in association with a phospholipid, such as dipalmitoylphosphatidylcholine (DPPC).
In the case where the fluorocarbon is used in association with a phospholipid, the molecular ratio between these two components preferably ranges from 1 to 300.
Only a small amount of fluorocarbon is necessary for improving the fluidity of the pulmonary surfactant monolayer.
The fluorocarbon is administered in liquid or vapor (gaseous) form, and preferably in a quantity corresponding of about 0.005 to about 4% of fluorocarbon in volume/kg body weight, preferably from about 0.005% to about 2% in volume/kg body weight.
The fluorocarbon may be administered neat or in the form of a water-in-fluorocarbon emulsion, or in the form of an oil-in-fluorocarbon emulsion.
The fluorocarbon composition may also serve as a drug delivery system. It is then contemplated that a further therapeutic agent can be dispersed in the fluorocarbon preparation.
The invention further provides a therapeutic composition comprising a fluorocarbon and a phospholipid, and optionally a therapeutic agent, e.g. prednisone or epinephrine.
In a preferred embodiment, the composition is in the form of an emulsion comprising a continuous phase of fluorocarbon. In a further preferred embodiment, the emulsion with a continuous fluorocarbon phase contains pulmonary pharmacologically active substance such as an antibiotic, a tuberculostatic antimycobacterial agent, an anticancer agent, a pulmonary vasoactive substance, etc.
Compounds useful in this invention (hereinafter called “fluorocarbons”) may be straight, branched or cyclic, saturated or unsaturated poly- or perfluorinated hydrocarbons. These compounds may also comprise heteroatoms such as oxygen or nitrogen, or halogen atoms other than fluorine, in particular bromine. Generally, the compound is liquid or gaseous at room temperature (25° C.). Preferably, the compound has from 2 to 12 carbon atoms. There is a large number of compounds compatible with the biomedical application described.
One may use for example straight or branched chain fluorocarbons such as perfluoropropane, perfluorobutane, perfluorohexane, perfluorooctane, bis(F-alkyl)ethenes, CnF2n+1CH═CHCn′F2n+1, such as iC3F9CH═CHC6F13 (“F-i36E”), C4F9CH═CHC4F9 (“F-44E”), C6F13CH═CHC6F13 (“F-66E”), cyclic fluorocarbons, such as C10F18 (F-decalin, perfluorodecalin or “FDC”), F-di- or F-trimethylbicyclo-3,3,1-nonane (“nonane”); perfluorinated amines, such as F-tripropylamine (“FTPA”) and F-tributylamine (“FTBA”), F-4-methyloctahydroquinolizine (“FMOQ”), F-n-methyldecahydroisoquinoline (“FMIQ”), F-n-methyldecahydroquinoline (“FHQ”), F-n-cyclohexylpyrrolidine (“FCHP”) and F-2-butyltetrahydrofuran (“FC-75” or “RM101”). Any other fluorocarbons contemplated for biomedical uses such as those described by Riess (Chemical Reviews (2001) 101:2797-2919) can be used.
Other fluorocarbons include brominated perfluorocarbons, such as 1-bromo-heptadecafluorooctane (C8F17Br, sometimes designated perfluorooctyl bromide or “PFOB”), 1-bromopentadecafluoroheptane (C7F15Br), and 1-bromotridecafluorohexane (C6F13Br, sometimes known as perfluorohexyl bromide or “PFHB”). Other brominated fluorocarbons are disclosed in U.S. Pat. No. 3,975,512. Also contemplated are fluorocarbons having other nonfluorine substituents, such as perfluorooctyl chloride, perfluorohexyl dichloride, perfluorooctyl hydride, and similar compounds having different numbers of carbon atoms.
Additional fluorocarbons contemplated in accordance with this invention include perfluoroalkylated ethers or polyethers, such as (CF3)2CFO(CF2CF2)2OCF(CF3)2; (CF3)2CFO(CF2CF2)3OCF(CF3); (CF3)CFO(CF2CF2)F; (CF3)2CFO(CF2CF2)2F; (C6F13)2O. Further, fluorocarbon-hydrocarbon compounds, such as, for example compounds having the general formula CnF2n+1Cn′H2n′+1 (also called semifluorinated alkanes or -FnHn′, CnF2n+1OCn′H2n′+1; or CnF2n+1CH═CHCn′H2n′+1, where n and n′ are the same or different and n ranges from 4 to 10 and n′ ranges from 2 to 20. Such compounds include, for example, perfluorooctylethane (C8F17C2H5, “PFOE”), perfluorohexylethane (C6F13C2H5, “PFHE”) and perfluorohexyldecane (C6F13C10H21, “F6H10”) or perfluorobutyl-1-undecene (C4F9CH═CHC10H21 “F4H8E”). It will be appreciated that esters, thioethers, and other variously modified mixed fluorocarbon-hydrocarbon compounds are also encompassed within the broad definition of “fluorocarbon” materials suitable for use in the present invention. Mixtures of fluorocarbons are also contemplated.
Preferred fluorocarbons are perfluorooctyl bromide (PFOB), bis(perfluorobutyl)ethene (F-44E) and perfluorooctylethane (PFOE).
In addition, the fluorocarbon may be neat or may be combined with other materials, such as surfactants (including fluorinated surfactants) and dispersed materials.
In particular, a therapeutic agent may be combined (e.g. dispersed) with the fluorocarbon.
Suitable therapeutic agents include, but are not limited to, antibiotics such as gentamicin, erythromycin and doxycycline; tuberculostatic antimycobacterials such as pyrazinamide, ethambutol and isoniazid; anticancerous agents such as cis-platinum, cyclophosphamide, 5-fluorouracyl and doxorubicin; pulmonary vasoactive substances and regulators of pulmonary hypertension such as tolazoline; respiratory stimulants such as doxapram; vasoactive bronchodilators or bronchostrictors such as acetylcholine, priscoline, epinephrine and theophylline; mucolytic agents such as acetylcysteine; steroids such as cortisone or prednisone; antiviral agents such as ribavirin.
There exist abundant data that demonstrate the biocompatibility of fluorocarbons. They are amenable to sterilization techniques. For example, they can generally be heat-sterilized (such as by autoclaving) or sterilized by radiation. In addition, sterilization by ultrafiltration is also contemplated.
The fluorocarbon can be provided as a liquid or in a gaseous form.
Inhalation or forced (positive pressure) introduction, either nasal or oral, of the fluorocarbon composition can be achieved by any of a variety of methods known in the art. These include mechanical suspension by agitation of the composition in a closed chamber followed by inhalation, or forced introduction of the suspension from an opening in the chamber. Microparticles can be inhaled from standard aerosol delivery systems that are well known in the art. The patient may receive a particulate suspension which is placed into an air stream such as by injection of the dispersed composition into a positive pressure ventilation tube or into an endotracheal tube at the moment of inspiration or when air is forced into the lungs. Metered dosages may be mechanically injected into such devices. The fluorocarbon composition may be dispersed in air by using the Venturi effect, where air is moved at right angles across a Venturi tube causing the fluorocarbon composition to be drawn through the tube and dispersed into the air that is inhaled or mechanically introduced into the lungs. Pulsatile delivery of the fluorocarbon composition in a volume of gas and inhalation of the aerosolized bolus is also known in the art as described in PCT published application WO 94/07514, and the delivery techniques described therein can be used in the present invention.
Liquid compositions of fluorocarbons may be directed to specific regions of the patient's pulmonary air passages by a number of different conventional means, such as a bronchoscope, a catheter, and the like.
The fluorocarbon introduced into the patient's lung may be in liquid or vapor form. The quantity of fluorocarbon composition administered may correspond to about 0.005 to about 4% of liquid fluorocarbon in volume/kg body weight, preferably from about 0.005% to about 2%.
The method of the invention improves the fluidity of the pulmonary surfactant, mainly by preventing the formation of crystalline islets of phospholipid, such as crystalline islets of DPPC, and/or by respreading the phospholipid islets that might have formed.
This is useful in the context of pulmonary surfactant deficiency, as in the diseases listed below.
In addition to RDS in neonates, ARDS in adults caused by severe hypovolemic shock, lung contusion, diver's lung, post-traumatic respiratory distress, post-surgical atelectasis, septic shock, multiple organ failure, Mendelssohn's disease, obstructive lung disease, pneumonia, pulmonary oedema or any other condition resulting in lung surfactant deficiency or respiratory distress are all candidates for fluorocarbon supplementation and the method of the invention.
Treatment of pulmonary fibrosis, emphysema, and chronic bronchitis can all benefit from fluorocarbon therapy as proposed herein.
In a preferred embodiment, the fluorocarbon is administered with a surfactant agent, e.g. a lipid or a phospholipid. The surfactant agent may be an amphiphilic molecule or a mixture of amphiphilic molecules, or may be a preparation of artificial lung surfactant, or may be extracted from human or mammal lung surfactant. Preferably, the surfactant agent is a phospholipid. The phospholipid may be a mixture of phospholipids. It is preferably selected from the group consisting of native pulmonary surfactant phospholipids, i.e. dipalmitoylphosphatidylcholine (DPPC), distearoylphosphatidylcholine, phosphatidylcholine (PC), phosphatidylglycerol (PG), dioleophosphatidylethanolamine (PE), dipalmitoylphosphatidylamine, sphingomyelin and phosphatidylinositol (PI), cardiolipids, soja and egg yolk phospholipids. In another embodiment, the fluorocarbon may also be administered with a mixture of phospholipids and glycoproteins, such as SP-A, SP-B, SP-C and SP-D, which are components of the native pulmonary surfactant composition. Fluorocarbon compounds are generally poorly soluble in water. Therefore, it is possible to prepare emulsions comprising a fluorocarbon compound, a phospholipid and water.
Such emulsions allow easy administration of both one or more fluorocarbons and one or more phospholipids at controlled dosage.
The emulsions may be prepared by mixing an aqueous phase and, dissolved or dispersed in the water, the phospholipid, with the fluorocarbon phase, optionally in presence of an additional suitable surfactant. One or both phases may further contain one or more therapeutic agents, as described above.
Appropriate surfactants include in particular fluorinated amphiphilic compounds such as fluorinated dimorpholinophosphate.
Preferably, the water phase is added slowly to the fluorinated phase containing an emulsifier, in particular a fluorinated surfactant.
The resulting pre-emulsion may then be homogenized, using procedures that are well known as such, in order to yield an emulsion with a narrow droplet size distribution.
In the case where the fluorocarbon is used in association with a phospholipid, the fluorocarbon/phospholipid molecular ratio between these two components preferably ranges from 1 to 300. In a preferred embodiment, the molecular ratio between phospholipid and the fluorocarbon ranges from 1 to 50.
An example of composition useful in the invention is a therapeutic composition comprising an emulsion of water in PFOB that contains DPPC. Another example of composition is a therapeutic composition comprising an emulsion of water in PFOE that contains DPPC.
Further examples of compositions include these above compositions supplemented with a pulmonary active agent, such as prednisone or epinephrine.
The invention thus contemplates the use of a fluorocarbon, optionally in combination with a surfactant agent, especially a phospholipid, e.g. a phospholipid of a native pulmonary surfactant, for the manufacture of a medicament intended for improving the spreadability and/or the fluidity of the native pulmonary surfactant in patients in need of such treatment.
The patients may be a human or a non-human animal, preferably a mammal. It may be a new-born patient, an infant, a child or an adult of any age.
The invention will be further illustrated by the following examples.
The monolayer of native pulmonary surfactant was modeled by a Langmuir monolayer of DPPC. In this model, the DPPC molecules were spread using a spreading solvent onto the surface of water contained in a trough coated with Teflon®. After evaporation of the solvent, the DPPC molecules were progressively compressed using two mobile Teflon® barriers. The variation of the surface pressure was measured as a function of the compression by a pressure sensor such as a Wilhelmy blade.
Small quantities of perfluorooctyl bromide (PFOB) in liquid form (1-200 μl), contacted with the DPPC monolayer, result in the disappearance of the liquid expanded/liquid condensed phase transition of the phospholipid. Thus, in presence of PFOB, the DPPC molecules did not form crystalline islets and respread easily on the water surface.
Placing the Langmuir trough in a close space saturated with PFOB vapour, it is possible to study the interactions between the DPPC monolayer and the gaseous PFOB. As shown in
The DPPC monolayer is totally fluid.
Fluorescence microscopy makes it possible to visualize the dissolution of crystalline islets of DPPC molecules when the monolayer is contacted with gaseous PFOB (
Similarly, when the DPPC monolayer is contacted with gaseous F-44E, the plateau reflecting the coexistence of the expanded liquid state and the condensed liquid state disappears, as shown in the compression isotherm of DPPC (
A grazing incidence X-ray diffraction study of the effect of gaseous F-44E on the DPPC monolayer clearly evidenced the disappearance of the crystalline islets and efficient re-spreading of the molecules of DPPC in the presence of gaseous F-44E (
2.50 ml of sterile PFOB were placed in the tank of vaporizer/pneumatic compressor such as the Omron CX3 aerosol, optionally fitted with a vaporization kit for Omron CX3, or any other vaporization system (Hudson TUp-draftII/Pulmo-aide, Airlife Mysty/Pulmo-Aide, Respirgard/Pulmo-aide, etc). PFOB was then vaporized according to the recommendations of the manufacturer.
6 ml of PFOB were introduced in an aluminium receptacle (Cebal, Clichy, France) (23.6×60×20 mm; 20 ml) (ST004, GL001 and TD 00033, Lablabo, Annemasse, France) that can contain a volume of 1 ml.
Using an appropriate filling system (Pamasol P20 16, Switzerland), 4 ml of 1,1,1,2,3,3,3-heptafluoropropane (HFA-227, Solkane® 227 pharma) were introduced into the aluminium receptacle. The receptacle was closed with a jet and a button.
The protocol of example 5 was followed by replacing HFA-227 by N2 and using an appropriate filling system.
An emulsion containing 5% v/v physiological water (NaCl solution 0.9% w/v), 3% w/v perfluorooctyl(undecyl)dimorpholinophosphate (F8H11DMP, used as the emulsifying agent) and 95% v/v PFOB was prepared. F8H11DMP (3 g) was dispersed in 95 ml of PFOB using a low energy mixer (Ultra-Turrax® T25 equipped with the S25N25F, Ika-Labortechnik, Stanfen, Germany) at a temperature below 40° C. 5 ml of physiological water were then added dropwise under constant agitation.
The pre-emulsion thus obtained was homogenized under high pressure using a Microfluidizer® 110T (Microfluidics, New Jersey, USA) for about 10 minutes at a temperature below 40° C. The emulsion thus obtained was opalescent, and the mean size of the water droplets was 60±5 nm (3000 Zeta Sizer, Malvern Instrument). This emulsion was sterilized by filtration through a 0.22 μm membrane before bottling in 10 ml flasks (with 8% hold-up volume). The mean size of the water droplets after one-year storage at 25° C. was 100±7 nm.
An emulsion containing 5% v/v water, 5% v/v DPPC, 3% w/v perfluorooctyl(undecyl)dimorpholinophosphate and 95% v/v PFOB, was prepared. The perfluorooctyl(undecyl)dimorpholinophosphate was dispersed in the PFOB using a low energy mixer (Ultra-Turrax) at a temperature below 40° C., as described in Example 7. Separately, a dispersion of DPPC (5% w/v) in physiological water was prepared using an Ultra-Turrax mixer. The aqueous phospholipid dispersion (5 ml) was then added dropwise to the fluorinated phase, while maintaining the agitation.
The pre-emulsion thus obtained was homogenized under high pressure using a Microfluidizer® 110T (Microfluidics, New Jersey, USA) for about 10 minutes at a temperature below 40° C. as described in Example 1. The emulsion thus obtained was opalescent, and the mean size of the water droplets was 70±5 nm (3000 Zeta Sizer, Malvern Instrument). This emulsion was sterilized, bottled and stored as described in Example 7. The mean size of droplets after one-year storage at 25° C. was 120±10 nm.
The emulsion is prepared following the protocol of Example 8, using PFOE instead of PFOB. An opalescent emulsion is obtained. The mean size of the water droplets was 65±5 nm (3000 Zeta Sizer, Malvern Instrument). The emulsion was sterilized, bottled and stored as described in Example 7. The mean size of the droplets after one-year storage at 25° C. was 110±10 nm.
An emulsion containing 5% v/v isotonic buffer (pH 3.0-3.5), 0.02 w/v epinephrine, 1% w/v DPPC, 3% w/v F8H11DMP (perfluorooctyl)undecyl dimorpholinophosphate) and 95% v/v PFOB is obtained as follows: 0.75 g F8H11DMP were dispersed in 23.75 ml of PFOB as described in Example 7. Separately, 0.25 g DPPC and 5 mg epinephrine were co-dispersed in 1.25 ml of isotonic buffer. This dispersion was added dropwise to the fluorinated phase under constant agitation. The pre-emulsion obtained was homogenised under high pressure with an Emulsiflex-B3® (Avestin, Ottawa, Canada). An opalescent emulsion was obtained, with water droplets of a mean size of 40±3 nm (3000 Zeta Sizer, Malvern Instrument). This emulsion was sterilized, bottled and stored as described in Example 7. The mean size of the droplets after one-year storage at 25° C. was 70±5 nm.
The emulsion was prepared following the protocol of Example 10, using PFOE instead of PFOB. An opalescent emulsion was obtained with droplets of a mean size of 55±5 nm (3000 Zeta Sizer, Malvern Instrument). The emulsion was sterilized, bottled and stored as described in Example 7. The mean size of the droplets after one year storage at 25° C. was 118±10 nm.
An emulsion containing 4.7% v/v physiological water, 0.02 w/v prednisone, 20% v/v perfluorobutyl-1-undecene (F4H8E), 4.7% v/v perfluorohexyldecane (F6H10), 4.8 w/v perfluorooctyl(undecyl)dimorpholinophosphate (F8H11DMP) and 67% v/v PFOB is obtained as follows: 2 mg prednisone are dissolved in 2 ml of F4H8E under agitation and moderate heating. 0.5 ml F6H10 and 7 ml PFOB (containing 0.5 g of F8H11DMP) were then subsequently added at room temperature. 0.5 ml of physiological water were then added to the solution under agitation using an Ultra-Turrax® T25. The pre-emulsion is then homogenised under high pressure using an Emulsiflex-B3®. An opalescent emulsion was obtained, with droplets of a mean size of 125±12 nm (3000 Zeta Sizer, Malvern Instrument). This emulsion was sterilized by membrane filtration and stored in vessels of 2.5 ml, as described in Example 7. The mean size of the droplets after six-month storage at 25° C. was 170±20 nm.
The emulsion was prepared following the protocol of Example 12, using PFOE instead of PFOB. An opalescent emulsion is obtained with droplets of a mean size of 146±15 nm (3000 Zeta Sizer, Malvern Instrument). The emulsion was sterilized, bottled and stored as described in Example 12. The mean size of the water droplets after six-months storage at 25° C. was 210±25 nm.
The emulsion prepared according to Example 7 was vaporised following the protocol described in Example 4.
(Propellent Gas: HFA-227)
The emulsion prepared according to Example 8 was aerosolized following the protocol described in Example 5.
(Propellent Gas: HFA-227)
The emulsion prepared according to Example 10 was aerosolized following the protocol described in Example 5.
(Propellent Gas: HFA-227)
The emulsion prepared according to Example 12 is aerosolized following the protocol described in Example 5.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB05/01020 | 4/18/2005 | WO | 12/18/2006 |
Number | Date | Country | |
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60563690 | Apr 2004 | US |