The present invention relates to a means of reducing alveolar surface tension and methods for promoting equitable liquid distribution amongst pulmonary alveoli in the presence of alveolar edema, all of which contribute to reducing ventilator-induced lung injury.
Physiology and Pathophysiology
Lung Physiology.
The terminal airspaces of the lungs, the alveoli, are lined with a thin liquid lining layer. Thus there is an air-liquid interface in the lungs that has an associated surface tension. Alveolar type II epithelial cells release lung surfactant—an aggregate of phospholipids and proteins—into the liquid lining layer. The surfactant adsorbs to and reduces surface tension at the air-liquid interface. By lowering surface tension, surfactant reduces the pressure required to keep the lungs inflated and reduces the work of breathing.
ARDS.
The acute respiratory distress syndrome (ARDS), can result from a variety of initial insults. ARDS has an incidence of about 200,000 cases per year in the United States, with a mortality rate exceeding 35%. For the purpose of the present disclosure, ARDS includes acute lung injury (ALI), which has been reclassified as mild ARDS.
In ARDS, inflammation is present in the lungs. With inflammation, pulmonary vascular permeability increases and liquid leaks out of the blood vessels into the surrounding interstitial tissue. The liquid carries plasma proteins with it. When enough liquid escapes from the vessels, liquid begins to enter the alveoli, a condition known as alveolar edema. Initially, discrete alveoli in the dependent (bottom portion of the) lung become flooded and are interspersed with alveoli that remain aerated. With disease progression, most alveoli in the dependent lung become flooded; in the nondependent lung, some alveoli become flooded and are interspersed with other alveoli that remain aerated. From the onset of edema, the additional liquid in the interstitium and airspace effectively thickens the alveolar-capillary membrane across which oxygen and carbon dioxide must pass, making gas exchange difficult. Further, in ARDS, lung compliance is reduced, which makes breathing difficult.
ARDS patients are treated by mechanical ventilation, which assists gas exchange and keeps patients alive but often causes an over-distension injury (ventilator-induced lung injury, VILI) that exacerbates the underlying lung disease and prevents patient recovery. It is now standard protocol to ventilate with a low tidal (breath) volume that has been shown to decrease mortality. However, mortality still exceeds 35%.
It has been hoped that administration of exogenous surfactant would reduce surface tension, increase lung compliance and protect against VILI. Thus, multiple randomized clinical trials have tested tracheal administration of exogenous surfactant in ARDS patients. However, exogenous surfactant administration has not reduced mortality, excepting in one pediatric study.
In VILI, the site of over-distension injury is likely in aerated alveoli adjacent to flooded alveoli. In flooded alveoli, the air-liquid interface forms a concave meniscus. Due to surface tension at the meniscus and pressure drop across the meniscus, flooded alveoli are shrunken and adjacent aerated alveoli are, due to interdependence, expanded. Mechanical ventilation significantly exacerbates the over-expansion of aerated alveoli located adjacent to flooded alveoli.
Neonatal Respiratory Distress Syndrome (RDS).
Surfactant production increases markedly during the third trimester of gestation. Premature babies born prior to or early in the third trimester used not to survive. Since the 1980's, tracheal instillation of exogenous surfactant has enabled such premature babies to live. However, there remains room for improvement in the clinical treatment of neonatal RDS.
High Frequency Modes of Lung Treatment.
For various objectives such as loosening/clearance of airway mucus and improved mechanical ventilation, the lung has sometimes been subjected to percussion or to high frequency ventilation. Devices designed to implement such treatments, and the frequencies at which they operate, include: pneumatically and electrically powered percussors; intrapulmonary percussive ventilation (1.7-5 Hz); flutter valve therapy; high-frequency chest wall oscillation (5-25 Hz); high frequency positive-pressure ventilation (1-1.8 Hz); high-frequency jet ventilation (up to 10 Hz); high-frequency oscillatory ventilation (1-50 Hz); high-frequency flow interruption (up to 15 Hz, where the flow interruption occurs during inspiration, not expiration); and high-frequency percussive ventilation (up to 2 Hz). None of these ‘high-frequency’ treatments operate at a frequency greater than 50 Hz.
Active Deflation.
Certain existing modes of mechanical ventilation have incorporated active deflation. Although now out of use, ventilation with negative end-expiratory pressure (NEEP)—available on Puritan Bennett AP series and Bird Mark 7 and 8 ventilators—can use a Venturi tube to actively draw air out of the airways and lower the minimal tracheal entrance pressure at end-expiration below atmospheric pressure. In a Venturi tube, a high pressure gas jet is forced through a small orifice at the tube end while a different gas enters through a second port at lower velocity. The jet accelerates the lower velocity gas by entrainment.
High-frequency oscillatory ventilation uses an oscillator to move a diaphragm at one end of a chamber that is incorporated into the mechanical ventilation circuit proximal to the endotracheal tube. On its forward stroke the oscillator compresses air within the chamber; on its backward stroke it expands air within the chamber. During the backward stroke, tracheal pressure may become negative. HFOV is most frequently used in neonatal ventilation, although it is used in adults as well.
In one aspect of the present invention, a surface tension-lowering agent is added to alveolar edema liquid to (i) directly lessen ventilation-induced over-distension injury of aerated alveoli located adjacent to flooded alveoli and (ii) promote equitable edema liquid redistribution among alveoli. Such surface tension lowering agents may include certain rhodamine dyes.
In another aspect of the present invention, an active, accelerated deflation method is applied during mechanical ventilation of the edematous lungs to promote equitable edema liquid redistribution between alveoli. An embodiment of the present invention includes an apparatus for generating such pressure waveforms.
In yet another aspect of the present invention, high frequency vibration of, or step or impulse force application to, the edematous lungs promotes equitable edema liquid redistribution among alveoli. Such vibrations, or step or impulse forces, may be applied by various means.
For a more complete understanding of the present invention, reference is made to the following detailed description of exemplary embodiments considered in conjunction with the accompanying drawings, in which:
Further, the degree of over-expansion of the aerated alveolus is injurious.
Referring to
The micrographs of
As discussed with respect to
The theory of
That flooded alveoli occasionally spontaneously clear suggests that the flooded state is a local, but not global, equilibrium. Thus it may be possible to overcome the pressure barrier ΔPBARRIER—equal to PLIQ•BORD at the border between two alveoli minus PLIQ•EDEM within the edematous alveolus and discussed above with respect to
To protect against ventilator-induced lung injury, the various aspects of the present invention provide approaches to reduce alveolar over-distension both directly, by lowering surface tension, and indirectly, by overcoming ΔPBARRIER to promote equal liquid distribution among alveoli. Such approaches include, but are not necessarily limited to:
Additives to alveolar flooding liquid were tested in the isolated rat lung model for their ability to reduce surface tension.
In the experiments of
To assess SRB efficacy over a range of albumin concentrations encompassing those present in ARDS, the lowest and highest effective SRB concentrations (i.e., 1 nM and 1 μM SRB) were tested in flooding solutions of normal saline containing 0% to 28% fatty acid-bound BSA and labeled with 31 μM fluorescein, at PALV=15 cmH2O.
As shown in the preceding discussions, the inventors of the present invention have discovered that the presence of albumin facilitates the surface activity of SRB. The tests described above were conducted using BSA. Further testing was performed using human serum albumin (HSA). The flooding solution used was about 5% (more specifically, 4.6%) fatty acid-bound albumin (BSA or HSA) in normal saline plus 31 μM fluorescein, with or without 1 μM SRB. Tests were performed at PALV=15 cmH2O.
In all micrographs of
From normalized alveolar liquid fluorescence intensity-time curves of the type shown in
To investigate how albumin may facilitate rhodamine activity, alternative substances were substituted for albumin, and alveolar surface tension was measured in the absence and presence of SRB. Lung regions were flooded with normal saline containing 4.6% fatty acid-bound BSA, 4.6% 70 kD dextran or 4.6% fibrinogen, plus 31 μM fluorescein. Surface tension was determined at PALV of 15 cmH2O. As shown in
Additional testing supported the conclusion that albumin facilitation is necessary for SRB to lower surface tension. Since it appeared from the tests discussed with respect to
Given the different effects of albumin and fibrinogen on the surface activity of SRB, rat blood plasma was substituted for the albumin solution used in previous tests, and the effect of SRB concentration on surface tension was determined. The plasma had a total protein concentration 3.9±0.4% (n=6). The results of these tests are summarized in
To investigate whether SRB is directly surface active in albumin solution, the surface tensions of solutions containing albumin and/or SRB were determined in vitro according to the following method. A 3 μL drop of normal saline that included 31 μM fluorescein and additional solutes as specified was placed on a steel plate, and the pressure within the test drop was measured through a hyperosmolar saline-filled glass micropipette with its tip immersed in the drop and its shank connected to a servo-nulling pressure-measurement system. The pipette and servo system were of the same type as discussed with respect to
The in vitro tests, summarized in
The additive experiments discussed above with respect to
Without being bound by theory, it is believed that SRB and RWT, incorporated into albumin-containing alveolar flooding liquid of the lungs as in embodiments of the present invention, lower surface tension, but it is not known whether they do so directly or by indirectly promoting adsorption to the interface of native lung surfactant, which is present in the lungs in vivo and in isolated rat lungs in situ. To rule out direct surface activity of SRB/RWT, the inventor used a fetal rat lung model deficient in surfactant (see
The following discussion presents a number of observations that should be taken into account when implementing embodiments of the present invention.
Effective Albumin Concentration Range.
SRB was found to lower surface tension when instilled in combination with 2.7% to 12% albumin solution. In ARDS, edema liquid albumin concentration averages about 3%. Thus, the albumin concentration range in which SRB is effective overlaps with the albumin concentration range present in clinical ARDS. To ensure that the albumin concentration in the alveolar liquid is sufficient for facilitating SRB, It might be necessary to administer supplemental albumin (albumin would most likely be administered intravascularly, but could be administered via the trachea) at the same time as SRB.
Further, SRB at 1 μM was found to lower surface tension in combination with 2.7% albumin solution, but not with rat blood plasma (
Rhodamine Dye-Albumin Interaction.
As discussed above, SRB and RWT require the presence of albumin, or potentially of an alternative facilitating solute such as might be present in plasma, in order to lower surface tension, whether in the absence of lung surfactant in vitro or in the presence of lung surfactant in situ in the isolated rat lung. SRB is known to bind to albumin. SRB is also known to interact with and increase the surface activity of the surfactant sodium dodecyl sulfate (SDS), suggesting that SRB might interact with lung surfactant phospholipids.
Amphiphilic SRB is, on its own, surface active. Computational modeling done by others suggest that the xanthene rings of SRB, despite the iminium cation that they support, constitute the hydrophobic moiety of SRB and that, when SRB adsorbs, the xanthene rings align with the interface. However SRB on its own is only surface active at greater than 1.3 mM, a concentration far greater than the 1 nM to 1 μM concentration range in which we found SRB, in conjunction with albumin, surface active. At the SRB concentrations that we tested, SRB on its own is not expected to alter surface tension. Accordingly, as discussed herein, addition of 1 μM SRB to a saline drop in vitro does not alter the surface tension of the drop (
SRB binds by hydrophobic interaction to the Sudlow site I of fatty acid-free albumin at a stoichiometry of about 1:1, with the hydrophobic xanthene rings of SRB likely situated in the albumin binding cavity. In the tests discussed in the present application, SRB at concentrations up to 1 μM were combined with 5% (0.7 mM) fatty acid-bound albumin. Given the low SRB concentration relative to that of albumin, it is likely that a significant fraction of the SRB was bound to albumin. How the presence of fatty acids affects the stoichiometry of SRB-albumin binding, however, might be directly tested, as it is possible that the quantity of bound fatty acids affects the efficacy of SRB in the presence of albumin.
In the in vitro experiments discussed in the present application, it was found that the surface tension of a solution containing both SRB and albumin was significantly lower, 24 mN/m, than that of a solution containing SRB or albumin alone (
Alternatively, SRB and albumin may interact with lung surfactant in situ in the isolated lungs. SRB, which at a given concentration is less surface active than SDS, is known to enhance the surface activity of SDS. Computational modeling done by others suggests that SRB inserts into the outer layer of SDS micelles—the xanthene rings of SRB, again, likely most embedded. However, the SRB concentration at which this facilitation of SDS has been shown to occur, 9 mM, is far greater than the SRB concentrations disclosed herein. Further, whether SRB/albumin affects alveolar epithelial type II cell secretion or reuptake of surfactant has not been investigated.
How SRB, albumin and lung surfactant interact is not known. As the xanthene rings of SRB embed in both albumin and in SDS micelles, it is unlikely that SRB links albumin to surfactant. Without being bound by theory, it is likely that SRB and albumin are already bound when the solution containing SRB and albumin is instilled into the lungs. Whether lung surfactant interacts with SRB or albumin, perhaps competing for SRB in a fashion that alters surface tension, remains to be determined.
SRB/RWT Chemistry.
SRB and RWT have a surface tension lowering capability that the dyes fluorescein, BCECF, calcein red-orange AM, and even sulforhodamine G lack. SRB and RWT also have an unique aspect to their chemical structure. While all six of the above dyes are aromatic fluorescent compounds, and all but calcein red-orange AM have anionic groups, SRB and RWT are distinguished by the additional presence of an iminium cation (R1=N+—R2R3). It would thus be expected that other molecules with structures similar to that of SRB and RWT would likewise promote surfactant adsorption and reduce surface tension when instilled into the lungs according to embodiments of the present invention. Aromatic dissociated salt anions possessing one or more carboxyl, hydroxyl, or equivalent groups plus one or more cationic groups may also act equivalently to SRB and RWT. Additives other than aromatic salts (e.g., zwitterionic salts) may also be effective in reducing surface tension when instilled into the lung.
RWT and SRB Toxicity.
Sulforhodamine B is approved as a food dye in Japan, and both SRB and RWT are used as ground water tracers. There is an extensive literature on the toxicity of these dyes. A brief survey of this literature reveals that most toxicity studies have been performed using dye formulations of unknown purity. The exception, summarized at the end of this section, is a series of SRB toxicity tests performed by a European Commission committee using high purity SRB.
Rhodamine WT has an LD50 of 430 mg/kg (5, 14). In limited in vivo testing of RWT, administration of 25-80% of the LD50 over 1-5 days did not cause histopathologic changes, increase the rate of micronuclei generation or increase the rate of occurrence of sperm abnormalities. Results of in vitro tests of RWT genotoxicity/mutagenicity, however, have been mixed. Rhodamine WT tested negative for genotoxicity at 4 mM by mammalian cell sister chromatid exchange and at 12 mM by mammalian cell chromosome aberration test. Yet RWT tested positive at about 2 to about 10 μM and 4 mM by Ames test and at about 2 to about 10 μM by mammalian cell chromosome aberration test. The purity of the dyes used in the above studies is not known and it is possible that purified RWT would test negative for genotoxicity. Based on the existing literature, however, RWT does not appear suitable for use as a clinical agent.
SRB of unknown purity tested negative for genotoxicity at about 2 μM to about 10 μM by Ames test; at 10 μM and 1.7 mM by Rec assay; and at about 2 μM to about 10 μM by mammalian cell chromosome aberration test. The only study in which SRB tested positive for genotoxicity is one in which the tested SRB concentration is not stated. In a series of tests on the cytotoxicity of Japanese food dyes, toxicity of SRB at 1 to 2 mM, which is greater than 1000 times the highest concentration at which the present application shows SRB to lower surface tension, was not found to be of cytotoxic concern, except for the detection of low level toxicity in cultured fetal rat cells at day four after plating that decreased by day seven. Further, following administration of 2000 mg/kg SRB to pregnant rats, there was no evidence of DNA damage in cells biopsied from dams or embryos.
A 2008 report by the Scientific Committee on Consumer Products of the European Commission presents SRB toxicity data from tests in which dye formulations of generally high purity were used. The LD50 for SRB (unknown purity) was found to exceed 1000 mg/kg. Administration of 1000 mg/kg/day of greater than 99% purity SRB for 13 weeks to mature rats produced no observable adverse effects. Administration of 1000 mg/kg/day of greater than 99% purity SRB for 12 days to pregnant rats produced no observable adverse effects in dams or fetuses. One-time administration of 2000 mg/kg of greater than 90% purity SRB to mice did not increase the rate of generation of micronuclei. A diet of 5% of greater than 99% purity SRB over two years was not carcinogenic in rats. Finally, SRB of greater than 99% purity tested negative for genotoxicity at 9 μmol/plate by Ames test and at 9 mM by mammalian cell chromosome aberration test. SRB appears to be a suitable candidate for clinical administration.
Potential Therapeutic Applications.
As disclosed in the present application, SRB concentrations of 1 nM to 100 nM effectively lower surface tension in both 4.6% albumin solution and in rat plasma (
In clinical applications of embodiments of the present invention, SRB, without or with supplemental albumin, could be delivered to the alveolus via the trachea or the vasculature. If delivered via the trachea, mechanical ventilation and diffusion should both propel SRB, or SRB and albumin, toward the alveoli. Concurrent tracheal instillation of exogenous surfactant might enhance SRB and/or albumin delivery by generating Marangoni flows toward the alveoli. It is also possible that SRB, without or with albumin or surfactant, could be instilled in more distal airway(s), e.g. via bronchoscope. SRB, without or with albumin, might be instilled in a concentrated bolus in the trachea or airways such that, once distributed throughout the lung edema liquid, SRB and albumin concentrations would be within the appropriate ranges for lowering surface tension.
An alternative route of SRB delivery, without or with supplemental albumin, would be via the vasculature. In ARDS, alveolar-capillary barrier permeability is sufficiently elevated to allow albumin entrance into the alveolus thus should also allow free- or albumin-bound SRB to diffuse out of the vasculature into the alveolar liquid phase. SRB delivery via the vasculature, which must also be investigated, holds potential as a new therapy for the treatment of ARDS.
Neonatal Respiratory Distress Syndrome.
A surface tension-lowering additive has potential application in the treatment neonatal RDS. Babies born prematurely before producing their own surfactant are treated by tracheal instillation of exogenous surfactant. Due to patchy aeration and/or surfactant delivery throughout the lungs of such premature infants, mechanical ventilation injures the alveolar-capillary barrier and albumin leaks from the blood into the lung liquid. Thus administration of an albumin-dependent surface tension lowering agent to the alveolar liquid in such premature infants has the potential to ameliorate neonatal RDS. As in ARDS, a surface tension lowering additive could be administered to neonates via the trachea, without or with exogenous surfactant and without or with supplemental albumin, or could be administered via the vasculatures, without or with supplemental albumin. Use of a surface tension lowering additive could improve treatment for neonatal RDS and/or lower the cost of treating neonatal RDS by decreasing the required exogenous surfactant dosage. In babies delivered just as they are beginning to produce native surfactant, SRB, RWT or equivalent might act as a bridge support by compensating for the low levels of native surfactant, or potentially enhancing the activity of the low levels of native surfactant, until more surfactant is produced.
Industrial Use of Additives.
Industrial surfactants are generally simpler in structure than pulmonary surfactant. Industrial surfactants are generally mono-molecular and may be positively charged, uncharged or negatively charged. Additives such as those discussed above might, by extension, be combined with albumin or an alternative facilitating solute and the combination might be used as an industrial surfactant or might be used in combination with an industrial surfactant to enhance surfactant adsorption and surface tension reduction.
2. Active Deflation During Mechanical Ventilation
According to embodiments of the present invention, sudden deflation of the lung will, effectively, catapult edema liquid out of the alveoli in which it is trapped. As discussed further herein, the effectiveness of this embodiment of the present invention has been demonstrated in the local alveolar edema model and global permeability edema model in the isolated, perfused rat lung.
In an embodiment of the present invention, the lung 50 is inflated to peak volume, and abrupt deflation is effected by simultaneous application of step voltage increases to valves 56, 58, causing the valves 56, 58 suddenly to close and open, respectively. Valve 58 remains open until the pressure measured in the tubing 46 has decreased to a targeted pressure, which may be the desired positive end-expiratory pressure, at which time voltage to valve 58 is returned to zero, causing valve 58 to close. At the subsequent, specified time for initiation of inflation, voltage to valve 56 is reduced exponentially such that valve 56 opens gradually and ventilation gas passes through valve 56 to inflate the lung 50. Thus, the lung 50 is actively deflated while maintaining a positive pressure at the lung 50. This maintenance of positive pressure at the lung 50 during mechanical deflation of the lung 50 is one of the characteristics of the present invention that distinguishes it over methods existing in the prior art.
The apparatus 44 of
In some embodiments of the present invention, the lung may be actively deflated at an accelerated rate (accelerated sawtooth), by applying vacuum pressure at gas outlet 54 of the ventilation apparatus 44 shown in
As discussed above with respect to
Either of the above two methods for causing active deflation, alone or in combination, could be combined with mechanical ventilation; non-invasive ventilation; or lung expansion devices including chest physiotherapy devices and high frequency oscillation devices.
Vacuum may be applied by known means such as vacuum pump, house vacuum line, Venturi tube, reciprocating piston or other mechanism. However, a distinguishing feature of the apparatus of
3. Vibration or Step or Impulse Force Application to the Lung
Lung motion during breathing is normally smooth. Application of vibration or of step or impulse force to the edematous lungs could perturb surface tension within edematous alveoli in such a fashion as to facilitate equitable edema liquid distribution.
Surface tension is normally spatially uniform in the lung.
Lung vibration could alter the normally uniform surface tension distribution.
If surface tension gradients existed along the interface 84, however, they would apply shear stress to, and cause movement of, the liquid 80 below in the interface 84. Thus, vibration of the lung, or application of a step or impulse force to the lung, would generate surface tension gradients at the air-liquid interface 84, and accompanying pressure gradients in the edema liquid 80 below the interface 84. Such induced spatial variation in the surface tension or pressure has the potential to overcome, at random, the pressure barrier trapping liquid in discrete alveoli, therefore to promote clearance of edematous alveoli.
Edematous alveolar liquid pressure is normally maximal at the edge of the alveolus. In the flooded alveolus, liquid pressure PLIQ-BORD at the edge of the alveolus exceeds liquid pressure PLIQ-EDEM in the center of the alveolus (see
When vibrating the lung from its periphery, sufficient amplitude is required to overcome damping as the signal propagates. A high frequency signal will travel better through water than air. Thus, the more edematous the lung, the more effective vibration will be as a therapy. In a droplet of pure water as small as an alveolus, the first resonant (rocking) mode would be expected to occur at about 5000 Hz. With the particular geometry of the edematous alveolar interface and inclusion of surfactant at the interface, the resonant frequency is not known, and, in view of the current state of art, is likely to require empirical investigation. Further, even non-resonant vibration could alter the normal edema liquid pressure distribution in a manner that favor alveolar clearance.
Given the tradeoff between amplitude and frequency, initial tests were performed in the relatively low frequency range of 100-200 Hz. With the local edema model and with the global permeability edema model, vibration of the lung was tested for its ability to clear flooded alveoli. A function generator was used to drive a speaker coil and the speaker cone was placed in contact with the lung surface, separated from the lung surface by saran wrap. As a control, the speaker cone was pressed against the lung surface with the same force as in the test, but in the absence of power to the speaker, such that the speaker cone did not vibrate. As discussed below with relation to
To apply vibrations of ≧50 Hz to the lung for edema liquid redistribution, the following methods could be employed individually, in combination and/or in conjunction with mechanical ventilation; non-invasive ventilation; or lung expansion devices including chest physiotherapy devices and high frequency oscillation devices, according to various embodiments of the present invention:
In some embodiments of the invention, a step or impulse force could be applied to the lung, rather than a vibration. In ideal form, step and impulse functions are of infinite frequency. The actual frequency of force application to the lung would not be infinite, but would be maximal. Thus, repetitive application of a step or impulse force to the lung would promote edematous alveolar clearance. A step or impulse function would be employed alone or in conjunction with mechanical ventilation; non-invasive ventilation; or lung expansion devices including chest physiotherapy devices and high frequency oscillation devices, by one of the following methods:
It will be understood that the embodiments described herein are merely exemplary and that a person skilled in the art may make many variations and modifications without departing from the spirit and scope of the invention. All such variations and modifications are intended to be included within the scope of the invention described in the claims appended hereto.
The present application claims the benefit of U.S. Provisional Patent Application No. 62/079,004, filed on Nov. 13, 2014, and is a continuation-in-part of U.S. patent application Ser. No. 13/650,759, filed on Oct. 12, 2012, which claims the benefit of U.S. Provisional Patent Application No. 61/547,133, filed on Oct. 14, 2011, all of which are incorporated by reference herein in their entireties.
Number | Name | Date | Kind |
---|---|---|---|
4216776 | Downie | Aug 1980 | A |
6180142 | Taeusch | Jan 2001 | B1 |
8967144 | Lurie | Mar 2015 | B2 |
9504796 | Perlman | Nov 2016 | B2 |
20090208581 | Edwards et al. | Aug 2009 | A1 |
20170021126 | Perlman | Jan 2017 | A1 |
Entry |
---|
Wang, Z. et al., Acylation of Pulmonary Surfactant Protein-C Is Required for Its Optimal Surface Active Interactions with Phospholipids, The Journal of Biological Chemistry, vol. 271, No. 32, (1996), 19104-19109. |
Ware, L. et al., The acute respiratory distress syndrome, N Engl J Med, 342: 1334-1349, 2000. |
Warr, R. et al., Low molecular weight human pulmonary surfactant protein (SP5): Isolation, characterization, and cDNA and amino acid sequences, Proc Natl Acad Sci USA, vol. 84, (1987), 7915-7919. |
Warriner, H. et al., A concentration-dependent mechanism by which serum albumin inactivates replacement lung surfactants, Biophys J, 82: 835-842, 2002. |
Weg, J. et al., Safety and potential efficacy of an aerosolized surfactant in human sepsis-induced adult respiratory distress syndrome, JAMA, 272: 1433-1438, 1994. |
Whitsett, J. et al., Hydrophobic Surfactant-Associated Protein in Whole Lung Surfactant and Its Importance for Biophysical Activity in Lung Surfactant Extracts Used for Replacement Therapy, Pediatric Research, vol. 20, No. 5, (1986), 460-467. |
Willson, D. et al., Surfactant for Pediatric Acute Lung Injury, Pediatr Clin N Am, 55, (2008), 545-575. |
Willson, D. et al., Effect of exogenous surfactant (calfactant) in pediatric acute lung injury: a randomized controlled trial, JAMA, 293: 470-476, 2005. |
Wu, Y. et al., Lung ventilation injures areas with discrete alveolar flooding, in a surface tension-dependent fashion, J Appl Physiol, 117: 788-796, 2014. |
Yapicioglu, H. et al., The use of surfactant in children with acute respiratory distress syndrome: efficacy in terms of oxygenation, ventilation and mortality, Pulmonary Pharmacology & Therapeutics, 16, (2003), 327-333. |
Yu, S. et al., Reconstitution of surfactant activity by using the 6 kDa apoprotein associated with pulmonary surfactant, Biochem J, 236, (1986), 85-89. |
Yu, S. et al., Characterization of the small hydrophobic proteins associated with pulmonary surfactant, Biochimica et Biophysica Acta, vol. 921, No. 3, (1987), 437-448. |
Yu, S. et al., Role of bovine pulmonary surfactant-associated proteins in the surface-active property of phospholipid mixtures, Biochim Biophys Acta, 1046: 233-241, 1990. |
Yu, S. et al., Effect of pulmonary surfactant protein A and neutral lipid on accretion and organization of dipalmitoylphosphatidycholine in surface films, Journal of Lipid Research, vol. 37, (1996), 1278-1288. |
Zasadzinski, J. et al., Inhibition of pulmonary surfactant adsorption by serum and the mechanisms of reversal by hydrophilic polymers: theory, Biophys J, 89: 1621-1629, 2005. |
Zasadzinski, J. et al., Overcoming rapid inactivation of lung surfactant: Analogies between competitive adsorption and colloid stability, Biochimica et Biophysica Acta, 1798, (2010), 801-828. |
Amizuka, T. et al., Surfactant therapy in neonates with respiratory failure due to haemorrhagic pulmonary oedema, Eur J Pediatr, 162, (2003), 697-702. |
Anzueto, A. et al., Aerosolized Surfactant in Adults with Sepsis-Induced Acute Respiratory Distress Syndrome. New Engl J Med 334: 1417-1422, 1996. |
Banerjee, R. et al., Ultrastructure of exogenous surfactants using cryogenic scanning electron microscopy, J Biomater Appl, 15, (2001), 230-240. |
Batenburg, J. et al., The lipids of pulmonary surfactant: dynamics and interactions with proteins. Prog Lipid Res 37: 235-276, 1998. |
Baumgart, F. et al., Palmitoylation of Pulmonary Surfactant Protein SP-C is Critical for Its Functional Cooperation with SP-B to Sustain Compression/Expansion Dynamics in Cholesterol-Containing Surfactant Films, Biophysical Journal, 99, (2010), 3234-3243. |
Bernhard, W. et al., Commercial versus Native Surfactants: Surface Activity, Molecular Components, and the Effect of Calcium, Am J Respir Crit Care Med, 162, (2000) 1524-1533. |
Berry, D. et al., Respiratory distress and surfactant inhibition following vagotomy in rabbits, J Appl Physiol, 61, (1986), 1741-1748. |
Bradbury, J., Could treatment of neonatal RDS improve further?, The Lancet, 360, (2002), p. 394. |
Braun, A. et al., A Freeze-Fracture Transmission Electron Microscopy and Small Angle X-Ray Diffraction Study of the Effects of Albumin, Serum and Polymers on Clinical Lung Surfactant Microstructure, Biophysical Journal, 93, (2007)123-139. |
Brower, R.G. et al., The Acute Respiratory Distress Syndrome Network. Ventilation with lower tidal volumes as compared with traditional tidal volumes for acute lung injury and the acute respiratory distress syndrome. N Engl J Med 342: 1301-1308, 2000. |
Cassidy, K. et al., Liquid Plug Flow in Straight and Bifurcating Tubes, Journal of Biomechanical Engineering, 123, (2001), 580-589. |
Clements, J., Lung Surfactant: A Personal Perspective, Annu Rev Physiol, 59, (1997) 1-21. |
Curstedt, T. et al., Different Effects of Surfactant Proteins B and C—Implications for Development of Synthetic Surfactants, Neonatology, 97, (2010), 367-372. |
De Prost, N. et al., Ventilator-induced lung injury: historical perspectives and clinical implications, Annals of Intensive Care, 1:28, (2011), 1-15. |
Dhar, P. et al., Liquid Protein Interactions Alter Line Tensions and Domain Size Distributions in Lung Surfactant Monolayers, Biophysical Journal, 102, (2012), 56-65. |
Diemel, R. et al., In vitro and in vivo intrapulmonary distribution of fluorescently labeled surfactant, Crit Care Med, vol. 30, No. 5, (2002), 1083-1090. |
Dijk, P. et al., A Comparison of the Hemodynamic and Respiratory Effects of Surfactant Instillation during Interrupted Ventilationversus Noninterrupted Ventilation in Rabbits with Severe Respiratory Failure, Pediatric Research, 45(2), (1999), 235-241. |
Ding, J. et al., Effects of Lung Surfactant Proteins, SP-B and SP-C, and Palmitic Acid onMonolayer Stability, Biophysical Journal, 80, (2001), 2262-2272. |
Dluhy, R. et al., Deacylated Pulmonary Surfactant Protein SP-C Transforms From a-Helical to Amyloid Fibril Structure via a pH-Dependent Mechanism: An Infrared Structural Investigation, Biophysical Journal, 85, (2003), 2417-2429. |
Dreyfuss, D. et al., Ventilator-induced lung injury: lessons from experimental studies. Am J Respir Crit Care Med 157: 294-323, 1998. |
Goss, C. et al., Incidence of acute lung injury in the United States, Crit Care Med, vol. 31, No. 6, (2003), 1607-1611. |
Greenough, A. Expanded use of surfactant replacement therapy, Eur J Pediatr, 159, (2000), 635-640. |
Gregory, T. et al., Surfactant chemical composition and biophysical activity in acute respiratory distress syndrome. J Clin Invest, 88, (1991), 1976-1981. |
Gregory, T. et al., Bovine surfactant therapy for patients with acute respiratory distress syndrome, Am J Respir Crit Care Med, 155, (1997), 1309-1315. |
Gunther, A. et al., Surfactant alterations in severe pneumonia, acute respiratory distress syndrome, and cardiogenic lung edema. Am J Respir Crit Care Med 153: 176-184,1996. |
Gustafsson, M. et al., Amyloid fibril formation by pulmonary surfactant protein C, FEBS Letters, 464, (1999), 138-142. |
Gustafsson, M. et al., Palmitoylation of a pulmonary surfactant protein C analogue affects the surface associated lipid reservior and film stability, Biochimica et Biophysica Acta, 1466 (2000) 169-178. |
Gustafsson, M. et al., The Palmitoyl Groups of Lung Surfactant Protein C Reduce Unfolding into a Fibrillogenic Intermediate, J Mol Biol, 310, (2001), 937-950. |
Hall, S. et al., Changes in Subphase Aggregates in Rabbits Injured by Free Fatty Acid, Am J Respir Crit Care Med, 149, (1994) 1099-1106. |
Halliday, H., Surfactants: past, present and future. J Perinatol 28, Suppl 1: S47-S56, 2008. |
Hallman, M. et al., Evidence of lung surfactant abnormality in respiratory failure. Study of bronchoalveolar lavage phospholipids, surface activity, phospholipase activity, and plasma myoinositol, J Clin Invest, 70: 673-683, 1982. |
Heldt, G. et al., Distribution of Surfactant, Lung Compliance, and Aeration of Preterm Rabbit Lungs after Surfactant Therapy and Conventional and High-Frequency Oscillatory Ventilation, Pediatric Research, vol. 31, No. 3, (1992), 270-275. |
Henry, M. et al., Ultrasonic Nebulized in Comparison with Instilled Surfactant Treatment of Preterm Lambs, Am J Respir Crit Care Med, 154, (1996), 366-375. |
Holm, B. et al., Content of Dipalmitoyl Phosphatidylcholine in Lung Surfactant: Ramifications for Surface Activity, Pediatric Research, 39(5), (1996), 805-811. |
Holm, B. et al., A biophysical mechanism by which plasma proteins inhibit lung surfactant activity, Chem Phys Lipids, 49, (1988) 49-55. |
Ikegami, M. et al., A Protein That Inhibits Surfactant in Respiratory Distress Syndrome, Biol Neonate, 50, (1986), 121-129. |
Jobe, A. et al., Lung protein leaks in ventilated lambs: effects of gestational age, Journal of Applied Physiology, vol. 58, No. 4, (1985), 1246-1251. |
Jobe, A. et al., Permeability of premature lamb lungs to protein and the effect of surfactant on that permeability, Journal of Applied Physiology, vol. 55, No. 1, (1983), 169-176. |
Johansson, J. et al., Molecular structures and interactions of pulmonary surfactant components, Eur J Biochem 244: 675-693,1997. |
Jordanova, A. et al., Influence of surfactant protein C on the interfacial behavior of phosphatidylethanolamine monolayers, Eur Biophys J, 38, (2009), 369-379. |
Kesecioglu, J. et al., Exogenous natural surfactant for treatment of acute lung injury and the acute respiratory listress syndrome, Am J Respir Crit Care Med, 180: 989-994, 2009. |
Kharge, A. et al., Sulforhodamine B interacts with albumin to lower surface tension and protect against ventilation injury of flooded alveoli. J Appl Physiol, 118, (2015), 355-364. |
Kharge, A. et al., Surface tension in situ in flooded alveolus unaltered by albumin, J Appl Physiol, 117: 440-451, 2014. |
Kitamura, M. et al., Binding of sulforhodamine B to human serum albumin: a spectroscopic study, Dyes Pigments, 99: 588-593, 2013. |
Kovacs, H. et al., The Effect of Environment on the Stability of an Integral Membrane Helix: Molecular Dynamics Simulations of Surfactant Protein C in Chloroform, Methanol and Water, J Mol Biol, 247, (1995), 808-822. |
Krause, M. et al., Alveolar Recruitment Promotes Homogeneous Surfactant Distribution in a Piglet Model of Lung Injury, Pediatric Research, vol. 50, No. 1, (2001), 34-43. |
Landmann, E. et al., Protein content and biophysical properties of tracheal aspirates form nennates with respiratory failure, Klin Padiatr, 214, (2002), 1-7. |
Lewis, J. et al., Altered Alveolar Surfactant Is an Early Marker of Acute Lung Injury in Septic Adult Sheep, American Journal of Respiratory and Critical Care Medicine, vol. 150, No. 1, (1994), 123-130. |
Lewis, J. et al., Lung function and surfactant distribution in saline-lavaged sheep given instilled vs. nebulized surfactant, Journal of Applied Physiology, vol. 74, No. 3, (1993), 1256-1264. |
Li, J. et al., The N-terminal Propeptide of Lung Surfactant Protein C is Necessary for Biosynthesis and Prevents Unfolding of a Metastable a-Helix, J Mol Biol, 338, (2004), 857-862. |
Liau, D. et al., Functional Abnormalities of Lung Surfactant in Experimental Acute Alveolar Injury in the Dog, Am Rev Respir Dis, 136, (1987), 395-401. |
Lukovic, D. et al., Production and characterisation of recombinant forms of human pulmonary surfactant protrain C (SP-C): Structure and surfact activity, Biochimica et Biophysica Acta, 1758, (2006), 509-518. |
Mazela, J. et al,. Comparison of poractant alfa and lyophilized lucinactant in a preterm lamb model of acute respiratory distress, Pediatric Research, vol. 72, No. 1, (2012), 32-37. |
Moison, R. et al., Plasma Proteins in Acute and Chronic Lung Disease of the Newborn, Free Radical Biology & Medicine, vol. 25, No. 3, (1998), 321-328. |
Morley, C., Systematic review of prophylactic vs rescue surfactant, Archives of Disease in Childhood, 77, (1997), F70-F74. |
Nakamura, H. et al., Monomolecular surface film and tubular myelin figures of the pulmonary surfactant in hamster lung, Cell Tissue Res, 241, (1985), 523-528. |
Nicholas, T. Pulmonary Surfactant: No mere paint on the alveolar wall, Respirology, 1, (1996), 247-257. |
Niemarkt, H. et al., Effects of less-invasive surfactant administration on oxygenation, pulmonary surfactant distribution, and lung compliance in spontaneously breathing preterm lamb, Pediatric Research, 76, (2014), 166-170. |
Notter, R. et al., Biophysical Activity of Synthetic Phospholipids Combined with Purified Lung Surfactant 6000 Dalton Apoprotein, Chemistry and Physics of Lipids, 44, (1987) 1-17. |
Otsubo, E. et al., Characterization of the Surface Activity of a Synthetic Surfactant with Albumin, Biol Pharm Bull, 25 (12), (2002), 1519-1523. |
Petty, T. et al., Abnormalities in Lung Elastic Properties and Surfactant Function in Adult Respiratory-Distress Syndrome. Chest 75: 571-574, 1979. |
Petty, T. et al., Characteristics of Pulmonary Surfactant in Adult Respiratory Distress Syndrome Associated with Trauma and Shock, American Review of Respiratory Disease, 115, (1977), 531-536. |
Phua, J. et al., Has mortality from acute respiratory distress syndrome decreased over time?: A systematic review, Am J Respir Crit Care Med, 179: 220-227, 2009. |
Pison, U. et al., Surfactant Abnormalities in Patients with Respiratory Failure after Multiple Trauma, Am Rev Respir Dis, 140: 1033-1039, 1989. |
Plasencia, I. et al., The N-terminal segment of pulmonary surfactant lipopeptide SP-C hasintrinsic propensity to interact with and perturb phospholipid bilayers, Biochem J, 377, (2004), 183-193. |
Polat, B. et al., An experimental and molecular dynamics investigation into the amphiphilic nature of sulforhodamine B, J Phys Chem B, 115: 1394-1402, 2011. |
Product Monograph, Curosurf, Chiesi Farmaceutici, Parma, Italy, Sep. 2009. |
Robertson, B. et al., Principles of surfactant replacement, Biochimica et Biophysica Acta, 1408, (1998) 346-361. |
Rooney, S., Lung Surfactant, Environmental Health Perspectives, 55, (1984), 205-226. |
Rubenfeld, G. et al., Incidence and outcomes of acute lung injury, N Engl J Med, 353: 1685-1693, 2005. |
Sarin, V. et al., Biophysical and biological activity of a synthetic 8.7-kDa hydrophobic pulmonary surfactant protein SP-B, Proc Natl Acad Sci USA, 87, (1990), 2633-2637. |
Schmidt, R. et al., Alteration of fatty acid profiles in different pulmonary surfactant phospholipids in acute respiratory distress syndrome and severe pneumonia, Am J Respir Crit Care Med, 163: 95-100, 2001. |
Scientific Committee on Consumer Products (SCCP), Health and Consumer Protection Directorate-General, European Commission. Opinion on Acid Red 52 (Online). http://ec.europa.eu/health/ph—risk/committees/04—sccp/docs/sccp—o—137.pdf [Jun. 24, 2008]. |
Seeger, W. et al., Alveolar surfactant and adult respiratory distress syndrome, Clin Investig, 71, (1993), 177-190. |
Seeger, W. et al., Surfactant inhibition by plasma proteins: differential sensitivity of various surfactant preparations, Eur Respir J, 6, (1993), 971-977. |
Seeger, W. et al., Differential sensitivity to fibrinogen inhibition of SP-C- vs. SP-B-based surfactants, Am J Physiol Lung Cell Mol Physiol, 262: L286-L291, 1992. |
Seeger, W. et al., Alteration of surfactant function due to protein leakage: special interaction with fibrin monomer, J Appl Physiol, 58: 326-338, 1985. |
Seehase, M. et al, New Surfactant with SP-B and C Analogs Gives Survival Benefit after Inactivation in Preterm Lambs, PLoS ONE, 7(10), (2012), e47631. |
Segerer, H. et al., Rapid Tracheal Infusion of Surfactant versus Bolus Instillation in Rabbits: Effects on Oxygenation, Blood Pressure and Surfactant Distribution, Biol Neonate, 69, (1996), 119-127. |
Smart, P. et al., An Evaluation of Some Fluorescent Dyes for Water Tracing, Water Resources Research, vol. 13, No. 1, (1977), 15-33. |
Smart, P., A review of the toxicity of twelve fluorescent dyes used for water tracing, NSS Bulletin, 46: 21-33, 1984. |
Speer, C. et al., Early versus late surfactant therapy in severe respiratory distress syndrome, Lung, Suppl, (1990), 870-876. |
Spragg, R. et al., Effect of recombinant surfactant protein C-based surfactant on the acute respiratory distress syndrome, N Engl J Med, 351: 884-892, 2004. |
Spragg, R. et al., Surfactant Replacement Therapy, Clinics in Chest Medicine, vol. 21, No. 3, (2000), 531-541. |
Spragg, R. et al., Recombinant surfactant protein C-based surfactant for patients with severe direct lung injury, Am J Respir Crit Care Med, 183: 1055-1061, 2011. |
St. Clair, C. et al., The Probability of Neonatal Respiratory Distress Syndrome as a Function ofGestational Age and Lecithin/Sphingomyelin Ratio, American Journal of Perinatology, vol. 25, No. 8, (2008), 473-480. |
Szyperski, T. et al., Pulmonary surfactant-associated polypeptide C in a mixed organic solvent transforms from a monomeric a-helical state into insoluble P-sheet aggregates, Protein Science, 7, (1998), 2533-2540. |
Taeusch, H. et al., Inactivation of pulmonary surfactant due to serum-inhibited adsorption and reversal by hydrophilic polymers: Experimental, Biophys J, 89: 1769-1779, 2005. |
Takahashi, A. et al Structure-function relationships of bovine pulmonary surfactant proteins: SP-B and SP-C, Biochim Biophys Acta, 1044: 43-49, 1990. |
Tanaka, Y. et al., Lung Surfactants. II. Effects of fatty acids, triacylglycerols and protein on the activity of lung surfactant, Chemical and Pharmaceutical Bulletin, vol. 31, No. 11, (1983), 4100-4109. |
Terry, M. et al., Pulmonary Distribution of Lucinactant and Poractant Alfa and Their Peridosing Hemodynamic Effects in a Preterm Lamb Model of Respiratory Distress Syndrome, Pediatric Research, vol. 68, No. 3, (2010), 193-198. |
Tierney, D. et al., Altered surface tension of lung extracts and lung mechanics, J Appl Physiol, 20: 1253-1260, 1965. |
Tsuda, S. et al., DNA damage induced by red food dyes orally administered to pregnant and male mice, Toxicol Sci, 61: 92-99, 2001. |
Ueda, T. et al., Distribution of surfactant and ventiliation in surfactant-treated preterm lambs, Journal of Applied Physiology, vol. 76, No. 1, (1994), 45-55. |
Veldhuizen, R. et al., Pulmonary surfactant subfractions in patients with the acute respiratory distress syndrome, Am J Respir Crit Care Med, 152: 1867-1871, 1995. |
Von Nahmen, A. et al., The phase behavior of lipid monolayers containing pulmonary surfactant protein C studied by fluorescence light microscopy, Eur Biophys, J, 26, (1997), 359-369. |
Voss, T. et al., Primary structure differences of human and surfactant-associated proteins isolated from normal and proteinosis lung, Biochimica et Biophysica Acts, 1138, (1992), 261-267. |
Walther, F. et al., Hydrophobic Surfactant Proteins and Their Analogues, Neonatology, 91, (2007), 303-310. |
Walther, F. et al., (2014), Surfactant protein C peptides with salt-bridges (“ion-locks”) promote high surfactant activities by mimicking the α-helix and membrane topography of the native protein, PeerJ 2:e485; DOI 10.7717/peerj.485, published Jul. 15, 2014. |
Walther, F. et al., A Synthetic Segment of Surfactant Protein A: Structure, in Vitro Surface Activity, and in Vivo Efficacy, Pediatric Research, 39(6), (1996), 938-946. |
Non-Final Office Action issued Dec. 11, 2015 in U.S. Appl. No. 13/650,759. |
Bachofen et al., “Experimental Hydrostatic Pulmonary Edema in Rabbit Lungs”, The American Review of Respiratory Disease, vol. 147, (1993), pp. 989-996. |
Brower et al., “Another “Negative” Trial of Surfactant, Time to Bury this Idea?”, American Journal of Respiratory and Critical Care Medicine, vol. 183, (2011), pp. 966-968. |
Cairo et al., “Mosby's Respiratory Care Equipment (Eighth Edition)”, 2011, pp. 217-228; 223-238; 377; 398-403 and D 685. |
Diemel, R. et al., In vitro and in vivo intrapulmonary distribution of fluorescently labeled surfactant, Grit Care Med, vol. 30, No. 5, (2002), 1083-1090. |
Gu, J. et al., (2007). Pathology and pathogenesis of severe acute respiratory syndrome. The American journal of pathology, 170(4), 1136-1147. |
Krishnan et al., “High-Frequency Ventillation for Acute Lung Injury and ARDS”, Chest, vol. 118, No. 3, Sep. 2000, pp. 795-807. |
National Center for Biotechnology Information. PubChem Compound Database; CID=65191, https://pubchem.ncbi.nlm.nik.gov/compound/65191 (accessed May 6, 2016. |
Perlman et al., “Micromechanics of Alveolar Edema”, American Journal of Respiratory Cell Molecular Biology, vol. 44, (2011) pp. 34-39. |
Scientific Committee of Consumer Products (SCCP), Health and Consumer Protection Directorate-General, European Commission. Opinion on Acid Red 52 (Online). http://ec.europe.eu/health/ph—risk/committees/04—sccp/docs/sccp—o—137.pdf [pdf Jun. 24, 2008]. |
Staub et al., “Pulmonary edema in dogs, especially the sequence of fluid accumulation in lungs”, Journal of Applied Physiology, vol. 22, No. 2, (1967), pp. 227-240. |
Stawicki et al., “High-Frequency Oscillatory Ventilation (HFOV) and Airway Pressure Release Ventillation (APRV): A Practical Guide”, Journal of Intensive Care Medicine, vol. 24, No. 4, Jul./Aug. 2009, pp. 215-229. |
Tsuchida et al., “Atelectasis Causes Alveolar Injury in Nonatelectatic Lung Regions”, American Journal of Respiratory Critical Care Medicine, vol. 174, (2006), pp. 279-289. |
Varisco, B. M. (2011), The pharmacology of acute lung injury in sepsis. Advances in pharmacological sciences, 2011. |
Wilkins et al., “Egan's Fundamentals of Respiratory Care”, Mosby, Inc. (2009), pp. 939-941. |
Number | Date | Country | |
---|---|---|---|
20160067210 A1 | Mar 2016 | US |
Number | Date | Country | |
---|---|---|---|
62079004 | Nov 2014 | US | |
61547133 | Oct 2011 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 13650759 | Oct 2012 | US |
Child | 14940675 | US |