Liquid breathing

Liquid breathing
Intervention
MeSH D021061

Liquid breathing is a form of respiration in which a normally air-breathing organism breathes an oxygen-rich liquid (such as a perfluorocarbon), rather than breathing air.

Perfluorochemical (perfluorocarbon) molecules have very different structures that impart different physical properties such as respiratory gas solubility, density, viscosity, vapor pressure, and lipid solubility.[1] Thus, it is critical to choose the appropriate PFC for a specific biomedical application, such as liquid ventilation, drug delivery or blood substitutes. The physical properties of PFC liquids vary substantially; however, the one common property is their high solubility for respiratory gases. In fact, these liquids carry more oxygen and carbon dioxide than blood.[2]

In theory, liquid breathing could assist in the treatment of patients with severe pulmonary or cardiac trauma, especially in pediatric cases. Liquid breathing has also been proposed for use in deep diving[3][4] and space travel.[5] Despite some recent advances in liquid ventilation, a standard mode of application has not yet been established.

Physicochemical properties (37 °C at 1 atm) of 18 perfluorochemical liquids used for biomedical applications. This table characterizes the most significant physical properties related to systemic physiology and their range of properties.
Gas solubility
Oxygen 33-66 mL / 100 mL PFC
Carbon dioxide 140-166 mL / 100 mL PFC
Vapor pressure 0.2-400 torr
Density 1.58-2.0 g/mL
Viscosity 0.8-8.0 cS

Approaches

Computer models of three perfluorochemical molecules used for biomedical applications and for liquid ventilation studies: a) FC-75, b) perflubron, and c) perfluorodecalin.

Because liquid breathing is still a highly experimental technique, there are several proposed approaches.

Total liquid ventilation

Although total liquid ventilation (TLV) with completely liquid-filled lungs can be beneficial,[6] the complex liquid-filled tube system required is a disadvantage compared to gas ventilation—the system must incorporate a membrane oxygenator, heater, and pumps to deliver to, and remove from the lungs tidal volume aliquots of conditioned perfluorocarbon (PFC). One research group led by Thomas H. Shaffer has maintained that with the use of microprocessors and new technology, it is possible to maintain better control of respiratory variables such as liquid functional residual capacity and tidal volume during TLV than with gas ventilation.[1][7][8][9] Consequently, the total liquid ventilation necessitates a dedicated liquid ventilator similar to a medical ventilator except that it uses a breatheable liquid. Many prototypes are used for animal experimentation, but experts recommend continued development of a liquid ventilator toward clinical applications.[10] Specific preclinical liquid ventilator (Inolivent) is currently under joint development in Canada and France.[11] The main application of this liquid ventilator is the ultra-fast induction of therapeutic hypothermia after cardiac arrest. This has been demonstrated to be more protective than slower cooling method after experimental cardiac arrest.[12]

Partial liquid ventilation

In contrast, partial liquid ventilation (PLV) is a technique in which a PFC is instilled into the lung to a volume approximating functional residual capacity (approximately 40% of total lung capacity). Conventional mechanical ventilation delivers tidal volume breaths on top of it. This mode of liquid ventilation currently seems technologically more feasible than total liquid ventilation, because PLV could utilise technology currently in place in many neonatal intensive-care units (NICU) worldwide.

The influence of PLV on oxygenation, carbon dioxide removal and lung mechanics has been investigated in several animal studies using different models of lung injury.[13] Clinical applications of PLV have been reported in patients with acute respiratory distress syndrome (ARDS), meconium aspiration syndrome, congenital diaphragmatic hernia and respiratory distress syndrome (RDS) of neonates. In order to correctly and effectively conduct PLV, it is essential to

  1. properly dose a patient to a specific lung volume (10–15 ml/kg) to recruit alveolar volume
  2. redose the lung with PFC liquid (1–2 ml/kg/h) to oppose PFC evaporation from the lung.

If PFC liquid is not maintained in the lung, PLV can not effectively protect the lung from biophysical forces associated with the gas ventilator.

New application modes for PFC have been developed.[14]

Partial liquid ventilation (PLV) involves filling the lungs with a fluid. This fluid is perfluorocarbon, also called Liquivent or Perflubron. The liquid has some unique properties. It has a very low surface tension, similar to surfactant, a substance that is produced in the lungs to prevent the alveoli from collapsing and sticking together during exhalation. It also has a high density, oxygen readily diffuses through it, and it may have some anti-inflammatory properties. In PLV, the lungs are filled with the liquid, the patient is then ventilated with a conventional ventilator using a protective lung ventilation strategy. This is called partial liquid ventilation. The hope is that the liquid will help the transport of oxygen to parts of the lung that are flooded and filled with debris, help remove this debris and open up more alveoli improving lung function. The study of PLV involves comparison to protocolized ventilator strategy designed to minimize lung damage.[15][16]

PFC vapor

Vaporization of perfluorohexane with two anesthetic vaporizers calibrated for perfluorohexane has been shown to improve gas exchange in oleic acid-induced lung injury in sheep.[17]

Predominantly PFCs with high vapor pressure are suitable for vaporization.

Aerosol-PFC

With aerosolized perfluorooctane, significant improvement of oxygenation and pulmonary mechanics was shown in adult sheep with oleic acid-induced lung injury.

In surfactant-depleted piglets, persistent improvement of gas exchange and lung mechanics was demonstrated with Aerosol-PFC.[18] The aerosol device is of decisive importance for the efficacy of PFC aerosolization, as aerosolization of PF5080 (a less purified FC77) has been shown to be ineffective using a different aerosol device in surfactant-depleted rabbits. Partial liquid ventilation and Aerosol-PFC reduced pulmonary inflammatory response.[19]

Proposed uses

Diving

Gas pressure increases with depth, rising 1 bar (14.5 psi (100 kPa)) every 10 meters to over 1,000 bar at the bottom of the Mariana Trench. Diving becomes more dangerous as depth increases, and deep diving presents many hazards. All surface-breathing animals are subject to decompression sickness, including aquatic mammals[20] and free-diving humans (see taravana). Breathing at depth can cause nitrogen narcosis and oxygen toxicity. Holding the breath while ascending after breathing at depth can cause air embolisms, burst lung, and collapsed lung.

Special breathing gas mixes such as trimix or heliox ameliorate the risk of decompression illness but do not eliminate it. Heliox further eliminates the risk of nitrogen narcosis but introduces the risk of helium tremors below 500 feet (152 meters). Atmospheric diving suits maintain body and breathing pressure at 1 bar, eliminating most of the hazards of descending, ascending, and breathing at depth. However, the rigid suits are bulky, clumsy, and very expensive.

Liquid breathing offers a third option,[3][21] promising the mobility available with flexible dive suits and the reduced risks of rigid suits. With liquid in the lungs, the pressure within the diver's lungs could accommodate changes in the pressure of the surrounding water without the huge gas partial pressure exposures required when the lungs are filled with gas. Liquid breathing would not result in the saturation of body tissues with high pressure nitrogen or helium that occurs with the use of non-liquids, thus would reduce or remove the need for slow decompression.

A significant problem, however, arises from the high viscosity of the liquid and the corresponding reduction in its ability to remove CO2.[3][22] All uses of liquid breathing for diving must involve total liquid ventilation (see above). Total liquid ventilation, however, has difficulty moving enough liquid to carry away CO2, because no matter how great the total pressure is, the amount of partial CO2 gas pressure available to dissolve CO2 into the breathing liquid can never be much more than the pressure at which CO2 exists in the blood (about 40 mm of mercury (Torr)).[22]

At these pressures, most fluorocarbon liquids require about 70 mL/kg minute-ventilation volumes of liquid (about 5 L/min for a 70 kg adult) to remove enough CO2 for normal resting metabolism.[23] This is a great deal of fluid to move, particularly as liquids are more viscous and denser than gases, (for example water is about 850 times the density of air[24]). Any increase in the diver's metabolic activity also increases CO2 production and the breathing rate, which is already at the limits of realistic flow rates in liquid breathing.[3][25][26] It seems unlikely that a person would move 10 liters/min of fluorocarbon liquid without assistance from a mechanical ventilator, so "free breathing" may be unlikely. However, it has been suggested that a liquid breathing system could be combined with a CO2 scrubber connected to the diver's blood supply; a US patent has been filed for such a method.[27][28]

Medical treatment

Computer-generated model of perflubron and gentamicin molecules in liquid suspension for pulmonary administration

The most promising area for the use of liquid ventilation is in the field of pediatric medicine.[29][30][31] The first medical use of liquid breathing was treatment of premature babies[32][33][34][35] and adults with acute respiratory distress syndrome (ARDS) in the 1990s. Liquid breathing was used in clinical trials after the development by Alliance Pharmaceuticals of the fluorochemical perfluorooctyl bromide, or perflubron for short. Current methods of positive-pressure ventilation can contribute to the development of lung disease in pre-term neonates, leading to diseases such as bronchopulmonary dysplasia. Liquid ventilation removes many of the high pressure gradients responsible for this damage. Furthermore, perfluorocarbons have been demonstrated to reduce lung inflammation,[36][37][38] improve ventilation-perfusion mismatch and to provide a novel route for the pulmonary administration of drugs.[39][40][41]

In order to explore drug delivery techniques that would be useful for both partial and total liquid ventilation, more recent studies have focused on PFC drug delivery using a nanocrystal suspension. The first image is a computer model of a PFC liquid (perflubron) combined with gentamicin molecules.

The second image shows experimental results comparing both plasma and tissue levels of gentamicin after an intratracheal (IT) and intravenous (IV) dose of 5 mg/kg in a newborn lamb during gas ventilation. Note that the plasma levels of the IV dose greatly exceed the levels of the IT dose over the 4 hour study period; whereas, the lung tissue levels of gentamicin when delivered by an intratracheal (IT) suspension, uniformly exceed the intravenous (IV) delivery approach after 4 hours. Thus, the IT approach allows more effective delivery of the drug to the target organ while maintaining a safer level systemically. Both images represent the in-vivo time course over 4 hours. Numerous studies have now demonstrated the effectiveness of PFC liquids as a delivery vehicle to the lungs.[42][43][44][45][46][47][48][49][50][51]

Comparison of IT and IV administration of gentamicin.

Clinical trials with premature infants, children and adults were conducted. Since the safety of the procedure and the effectiveness were apparent from an early stage, the US Food and Drug Administration (FDA) gave the product "fast track" status (meaning an accelerated review of the product, designed to get it to the public as quickly as is safely possible) due to its life-saving potential. Clinical trials showed that using perflubron with ordinary ventilators improved outcomes as much as using high frequency oscillating ventilation (HFOV). But because perflubron was not better than HFOV, the FDA did not approve perflubron, and Alliance is no longer pursuing the partial liquid ventilation application. Whether perflubron would improve outcomes when used with HFOV or has fewer long-term consequences than HFOV remains an open question.

In 1996 Mike Darwin and Steven B. Harris proposed using cold liquid ventilation with perfluorocarbon to quickly lower the body temperature of victims of cardiac arrest and other brain trauma to allow the brain to better recover.[52] The technology came to be called gas/liquid ventilation (GLV), and was shown able to achieve a cooling rate of 0.5 °C per minute in large animals.[53] It has not yet been tried in humans.

Most recently, hypothermic brain protection has been associated with rapid brain cooling. In this regard, a new therapeutic approach is the use of intranasal perfluorochemical spray for preferential brain cooling.[54] The nasopharyngeal (NP) approach is unique for brain cooling due to anatomic proximity to the cerebral circulation and arteries. Based on preclinical studies in adult sheep, it was shown that independent of region, brain cooling was faster during NP-perfluorochemical versus conventional whole body cooling with cooling blankets. To date, there have been four human studies including a completed randomized intra-arrest study (200 patients).[55][56] Results clearly demonstrated that prehospital intra-arrest transnasal cooling is safe, feasible and is associated with an improvement in cooling time.

Space travel

Liquid immersion provides a way to reduce the physical stress of G forces. Forces applied to fluids are distributed as omnidirectional pressures. Because liquids cannot be practically compressed, they do not change density under high acceleration such as performed in aerial maneuvers or space travel. A person immersed in liquid of the same density as tissue has acceleration forces distributed around the body, rather than applied at a single point such as a seat or harness straps. This principle is used in a new type of G-suit called the Libelle G-suit, which allows aircraft pilots to remain conscious and functioning at more than 10 G acceleration by surrounding them with water in a rigid suit.

Acceleration protection by liquid immersion is limited by the differential density of body tissues and immersion fluid, limiting the utility of this method to about 15 to 20 G.[57] Extending acceleration protection beyond 20 G requires filling the lungs with fluid of density similar to water. An astronaut totally immersed in liquid, with liquid inside all body cavities, will feel little effect from extreme G forces because the forces on a liquid are distributed equally, and in all directions simultaneously. However effects will be felt because of density differences between different body tissues, so an upper acceleration limit still exists.

Liquid breathing for acceleration protection may never be practical because of the difficulty of finding a suitable breathing medium of similar density to water that is compatible with lung tissue. Perfluorocarbon fluids are twice as dense as water, hence unsuitable for this application.[2]

Examples in fiction

See also

References

  1. 1 2 Shaffer, Thomas H.; Wolfson, Marla R.; Clark, Leland C. (October 1992). "Liquid ventilation". Pediatric Pulmonology. 14 (2): 102–109. doi:10.1002/ppul.1950140208. PMID 1437347.
  2. 1 2 Gabriel, J. L.; Miller Jr, T. F.; Wolfson, M. R.; Shaffer, T. H. (1996). "Quantitative structure-activity relationships of perfluorinated hetero-hydrocarbons as potential respiratory media: application to oxygen solubility, partition coefficient, viscosity, vapor pressure, and density". ASAIO Journal. 42 (6): 968–973. doi:10.1097/00002480-199642060-00009. PMID 8959271.
  3. 1 2 3 4 Kylstra JA (1977). The Feasibility of Liquid Breathing in Man. Report to the US Office of Naval Research. Durham, NC: Duke University. Retrieved 2008-05-05.
  4. "menfish". Retrieved 2008-05-17.
  5. "Liquid Breathing - Medical uses". Archived from the original on 2010-04-15. Retrieved 2008-05-17.
  6. Wolfson (2008). "Multicenter comparative study of conventional mechanical gas ventilation to tidal liquid ventilation in oleic acid injured sheep". 54 (3): 236–269.
  7. Cox CA, Stavis RL. Wolfson MR, Shaffer TH; Stavis; Wolfson; Shaffer (2003). "Long-term tidal liquid ventilation in premature lambs: Physiologic, biochemical and histological correlates". Biol. Neonate. 84 (3): 232–242. doi:10.1159/000072307. PMID 14504447.
  8. Libros, R; Philips, CM; Wolfson, MR; Shaffer, TH (2000). "A perfluorochemical loss/restoration (L/R) system for tidal liquid ventilation". Biomed Instrum & Technol. 34 (5): 351–360.
  9. Heckman, JL; Hoffman, J; Shaffer, TH; Wolfson, MR (1999). "Software for real-time control of a tidal liquid ventilator". Biomedical Instrumentation & Technology. 33 (3): 268–276.
  10. Costantino, ML; Micheau, P; Shaffer, TH; Tredici, S; et al. (2009). "Clinical design functions: Round table discussions on bioengineering of liquid ventilators". ASAIO J. 55 (3): 206–8. doi:10.1097/MAT.0b013e318199c167. PMID 19282746.
  11. http://www.inolivent.ca/?lang=en
  12. Kohlhauer M, Lidouren F, Remy-Jouet I, Mongardon N, Adam C, Bruneval P, Hocini H, Levy Y, Blengio F, Carli P, Vivien B, Ricard JD, Micheau P, Walti H, Nadeau M, Robert R, Richard V, Mulder P, Maresca D, Demené C, Pernot M, Tanter M, Ghaleh B, Berdeaux A, Tissier R (2015). "Hypothermic Total Liquid Ventilation Is Highly Protective Through Cerebral Hemodynamic Preservation and Sepsis-Like Mitigation After Asphyxial Cardiac Arrest". Crit. Care Med. 43 (10): 420–30. doi:10.1097/CCM.0000000000001160. PMID 26110489.
  13. Clark, LC; Gollan, F (1966). "Survival of mammals breathing organic liquids equilibrated with oxygen at atmospheric pressure". Science. 152 (3730): 1755–6. Bibcode:1966Sci...152.1755C. doi:10.1126/science.152.3730.1755. PMID 5938414.
  14. Hlastala, MP; Souders, JE (July 1, 2001). "Perfluorocarbon Enhanced Gas Exchange: The easy way". American Journal of Respiratory and Critical Care Medicine. 164 (1): 1–2. doi:10.1164/ajrccm.164.1.2104021a. PMID 11435228. A significant positive step was the use of PFC-associated gas exchange, now termed partial liquid ventilation (PLV).
  15. Hirschl, RB; Pranikoff, T; Wise, C; Overbeck, MC; et al. (1996). "Initial experience with partial liquid ventilation in adult patients With the acute respiratory distress syndrome". JAMA. 275 (5): 383–389. doi:10.1001/jama.1996.03530290053037.
  16. Verbrugge, SJC; Lachmann, B (September 1, 1997). "Partial liquid ventilation" (PDF). European Respiratory Journal. 10 (9): 1937–9. doi:10.1183/09031936.97.10091937. PMID 9311481. (editorial)
  17. "Vaporization is a new application technique for perfluorocarbon that significantly improved oxygenation and pulmonary function in oleic acid-induced lung injury." Bleyl JU; et al. (1999). "Vaporized perfluorocarbon improves oxygenation and pulmonary function in an ovine model of acute respiratory distress syndrome". Anesthesiology. 91 (2): 340–2. doi:10.1097/00000542-199908000-00021. PMID 10443610.
  18. Kandler, Michael A.; Von Der Hardt, Katharina; Schoof, Ellen; Dötsch, Jörg R.; Rascher, Wolfgang (2001). "Persistent Improvement of Gas Exchange and Lung Mechanics by Aerosolized Perfluorocarbon". American Journal of Respiratory and Critical Care Medicine. 164 (1): 31–35. doi:10.1164/ajrccm.164.1.2010049. PMID 11435235. Aerosolized perfluorocarbon improved pulmonary gas exchange and lung mechanics as effectively as PLV did in surfactant-depleted piglets, and the improvement was sustained longer.
  19. Von Der Hardt, Katharina; Schoof, Ellen; Kandler, Michael A.; Dötsch, Jörg R.; Rascher, Wolfgang (2002). "Aerosolized Perfluorocarbon Suppresses Early Pulmonary Inflammatory Response in a Surfactant-Depleted Piglet Model". Pediatric Research. 51 (2): 177–182. doi:10.1203/00006450-200202000-00009. PMID 11809911. In a surfactant-depleted piglet model, aerosol therapy with perfluorocarbon but not LV-PLV reduces the initial pulmonary inflammatory reaction at least as potently as PLV at FRC volume.
  20. Lippsett, Lonny (5 April 2005). "Even Sperm Whales Get the Bends". Oceanus. Woods Hole Oceanographic Institution. 44 (1). Archived from the original on 5 June 2010. Retrieved 3 August 2010.
  21. Kylstra JA (September 1974). "Liquid breathing". Undersea Biomed Res. 1 (3): 259–69. PMID 4619862. Retrieved 2008-05-05.
  22. 1 2 Matthews WH, Kylstra JA (June 1976). "A fluorocarbon emulsion with a high solubility for CO2". Undersea Biomed Res. 3 (2): 113–20. PMID 951821. Retrieved 2008-05-05.
  23. Miyamoto Y.; Mikami T. (1976). "Maximum capacity of ventilation and efficiency of gas exchange during liquid breathing in guinea pigs". Jpn. J. Physiol. 26 (6): 603–618. doi:10.2170/jjphysiol.26.603. PMID 1030748.
  24. Sherwood, Lauralee; Klandorf, Hillar; Yancey, Paul H. (2005). Animal Physiology: From Genes to Organisms. Southbank, Victoria, Australia: Thomson/Brooks/Cole. ISBN 0-534-55404-0. OCLC 224468651.
  25. Koen, P. A.; Wolfson, M. R.; Shaffer, T. H. (1988). "Fluorocarbon ventilation: maximal expiratory flows and CO2 elimination". Pediatr Res. 24: 291–296. PMID 3145482.
  26. Matthews WH, Balzer RH, Shelburne JD, Pratt PC, Kylstra JA (December 1978). "Steady-state gas exchange in normothermic, anesthetized, liquid-ventilated dogs". Undersea Biomed Res. 5 (4): 341–54. PMID 153624. Retrieved 2008-05-05.
  27. Taylor, Jerome (20 November 2010). "Into the abyss: The diving suit that turns men into fish" (20 November 2010). Independent Print Ltd. The Independent. Retrieved 20 October 2015.
  28. Artificial gills for deep diving without incurring the bends and for scavenging O2 from and dispelling CO2 into water or thin air US Patent #8,631,788, published 21 Jan 2014.
  29. Wolfson, MR; Kechner, NE; Roache, RF; Dechadarevian, JP; et al. (1998). "Perfluorochemical rescue after surfactant treatment: Effect of perflubron dose and ventilatory frequency". J Appl Physiol. 84 (2): 624–640. PMID 9475875.
  30. Stavis, RL; Wolfson, MR; Cox, C; Kechner, N; Shaffer, TH (January 1998). "Physiologic, biochemical, and histologic correlates associated with tidal liquid ventilation". Pediatric Research. 43 (1): 132–138. doi:10.1203/00006450-199801000-00020. PMID 9432124.
  31. Wolfson, MR; Shaffer, TH (June 2005). "Pulmonary applications of perfluorochemical liquids: Ventilation and beyond" (PDF). Paediatric Respiratory Reviews. 6 (2): 117–127. doi:10.1016/j.prrv.2005.03.010. PMID 15911457. Archived from the original (PDF) on 2013-12-17.
  32. Greenspan, JS; Wolfson, MR; Rubenstein, SD; Shaffer, TH (1989). "Liquid ventilation of preterm baby". The Lancet. 2 (8671): 1095. doi:10.1016/S0140-6736(89)91101-X. PMID 2572810.
  33. Greenspan, JS; Wolfson, MR; Rubenstein, SD; Shaffer, TH (July 1990). "Liquid ventilation of human preterm neonates". The Journal of Pediatrics. 117 (1 Pt 1): 106–11. PMID 2115078.
  34. Leach, CL; Greenspan, JS; Rubenstein, SD; Shaffer, TH; et al. (September 1996). "Partial liquid ventilation with perflubron in premature infants with severe respiratory distress syndrome. The LiquiVent Study Group". The New England Journal of Medicine. 335 (11): 761–7. doi:10.1056/NEJM199609123351101. PMID 8778584.
  35. Greenspan, JS; Fox, WW; Rubenstein, SD; Wolfson, MR; Spinner, SS; Shaffer, TH (1997). "Partial liquid ventilation in critically ill infants receiving extracorporeal life support. Philadelphia Liquid Ventilation Consortium". Pediatrics. 99 (1): E2. doi:10.1542/peds.99.1.e2. PMID 9096170.
  36. Brunelli, L; Hamilton, E; Davis, JM; Koo, HC; et al. (2006). "Perfluorochemical liquids enhance delivery of superoxide dismutase to the lungs of juvenile rabbits". Pediatr Res. 60 (1): 65–70. doi:10.1203/01.pdr.0000219392.73509.70. PMID 16690961.
  37. "Perfluorochemical liquids modulate cell-mediated inflammatory responses". Critical Care Medicine. 29 (9): 1731–7. 2001. doi:10.1097/00003246-200109000-00013. PMID 11546973.
  38. Ramesh Babu, PB; Chidekel, A; Shaffer, TH (March 2005). "Hyperoxia-induced changes in human airway epithelial cells: The protective effect of perflubron". Pediatric Critical Care Medicine. 6 (2): 188–194. doi:10.1097/01.PCC.0000154944.67042.4F. PMID 15730607.
  39. Brunelli et al.
  40. Cox, CA; Cullen, AB; Wolfson, MR; Shaffer, TH (August 2001). "Intratracheal administration of perfluorochemical-gentamicin suspension: A comparison to intravenous administration in normal and injured lungs". Pediatric Pulmonology. 32 (2): 142–151. doi:10.1002/ppul.1100. PMID 11477731.
  41. Fox, WW; Weis, CM; Cox, C; Farina, C; et al. (November 1997). "Pulmonary administration of gentamicin during liquid ventilation in a newborn lamb lung injury model". Pediatrics. 100 (5): E5. doi:10.1542/peds.100.5.e5. PMID 9346999.
  42. Wolfson MR, Greenspan JS, Shaffer TH. Pulmonary adminis¬tration of vasoactive substances by perfluorochemical ventilation" Pediatrics 1996;97(4) 449-455.
  43. Kimless Garber DB, Wolfson MR, Carlsson C, Shaffer TH. Halothane administration during liquid ventila¬tion. Respir Med. 1997; 91(5) 255-262.
  44. Zelinka MA, Wolfson MR, Calligaro I, Rubenstein SD, Greenspan JS, Shaffer TH (1997). "A comparison of intratracheal and intravenous administration of gentamicin during liquid ventilation". Eur J Pediatr. 156 (5): 401–404. doi:10.1007/s004310050625.
  45. Lisby DA, Ballard PL, Fox WW, Wolfson MR, Shaffer TH, Gonzales LW (1997). "Enhanced distribution of adenovirus-mediated gene transfer to lung parenchyma by perfluorochemical liquid". Hum Gene Ther. 8 (8): 919–928. doi:10.1089/hum.1997.8.8-919.
  46. Fox WW, Weis CM, Cox C, Farina C, Drott H, Wolfson MR, Shaffer TH (1997). "Pulmonary administration of gentamicin during liquid ventilation in a newborn lamb lung injury model". Pediatrics. 100 (5): E5. doi:10.1542/peds.100.5.e5. PMID 9346999.
  47. Cullen AB, Cox CA, Hipp SJ, Wolfson MR, Shaffer TH (1999). "Intra-tracheal delivery strategy of gentamicin with partial liquid ventilation". Respir Med. 93 (11): 770–778. doi:10.1016/s0954-6111(99)90261-5.
  48. Cox CA, Cullen AB, Wolfson MR, Shaffer TH (2001). "Intratracheal administration of perfluorochemical-gentamicin suspension: a comparison to intravenous administration in normal and injured lungs". Pediatr Pulmonol. 32 (2): 142–151. doi:10.1002/ppul.1100. PMID 11477731.
  49. Chappell SE, Wolfson MR, Shaffer TH (2001). "A comparison of surfactant delivery with conventional mechanical ventilation and partial liquid ventilation in meconium aspiration injury". Respir Med. 95 (7): 612–617. doi:10.1053/rmed.2001.1114.
  50. Brunelli L, Hamilton E, Davis JM, Koo HC, Joseph A, Kazzaz JA, Wolfson MR, Shaffer TH (2006). "Perfluorochemical liquids enhance delivery of superoxide dismutase to the lungs of juvenile rabbits". Pediatr Res. 60 (1): 65–70. doi:10.1203/01.pdr.0000219392.73509.70. PMID 16690961.
  51. Constantino ML, Shaffer TH, Wauer RR, Rudiger M (2006). "The 5th European Symposium on Perfluorocarbon (PFC) Application". ASAIO J. 52 (4): 483–494.
  52. Darwin, MG (1996). "Liquid ventilation: A bypass on the way to bypass". BPI Tech Briefs. 19.
  53. Harris, SB; Darwin, MG; Russell, SR; O'Farrell, JM; et al. (2001). "Rapid (0.5°C/min) minimally invasive induction of hypothermia using cold perfluorochemical lung lavage in dogs". Resusciation. 50 (2): 189–204. doi:10.1016/S0300-9572(01)00333-1. PMID 11719148.
  54. Wolfson; et al. (2008). "Intranasal perfluorochemical spray for preferential brain cooling in sheep". Neurocrit Care. 8 (3): 437–47. doi:10.1007/s12028-008-9064-0.
  55. Castrén M, Nordberg P, Svensson L, et al. (Aug 2010). "Intra-arrest transnasal evaporative cooling: a randomized, prehospital, multicenter study (PRINCE: Pre-ROSC IntraNasal Cooling Effectiveness)". Circulation. 122 (7): 729–36. doi:10.1161/circulationaha.109.931691.
  56. Busch HJ, Eichwede F, Födisch M, et al. (Aug 2010). "Safety and feasibility of nasopharyngeal evaporative cooling in the emergency department setting in survivors of cardiac arrest". Resuscitation. 81 (8): 943–9. doi:10.1016/j.resuscitation.2010.04.027. PMID 20627524.
  57. Guyton, Arthur C. (1986). "Aviation, Space, and Deep Sea Diving Physiology". Textbook of Medical Physiology (7th ed.). W. B. Saunders Company. p. 533.
  58. Harmetz, Aljean (August 6, 1989). "'The Abyss': A Foray Into Deep Waters". New York Times.
  59. McNeill, Graham (2008). Mechanicum: war comes to Mars (mass market paperback) (print). Horus Heresy. 9. Cover art & illustration by Neil Roberts; map by Adrian Wood (1st UK ed.). Nottingham, UK: Black Library. pp. 64, 149. ISBN 978-1-84416-664-0. The amniotic tanks are referenced in several other places in the novel.
  60. https://forums.eveonline.com/default.aspx?g=posts&m=3479925#post3479925
  61. Westerfeld, Scott (2003). The Risen Empire. ISBN 0-7653-0555-0.
  62. van Eekhout, Greg (2014). California Bones. ISBN 978-0765328557.
This article is issued from Wikipedia - version of the 12/5/2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.