Перевести страницу на:  
Please select your language to translate the article


You can just close the window to don't translate
Библиотека
ваш профиль

Вернуться к содержанию

Исследования космоса
Правильная ссылка на статью:

Wheeler Raymond Agriculture for Space: People and Countries Paving the Way

Аннотация: Agricultural systems for space have been discussed since the works of Tsiolkovsky in the early 20th century. Central to the concept is the use of photosynthetic organisms and light to generate oxygen and food. Research in the area started in 1950s and 60s through the works of Jack Myers and others, who studied algae for O2 production and CO2 removal for the US Air Force and NASA. Studies on algal production and controlled environment agriculture were also carried out by Russian researchers in Krasnoyarsk, beginning in 1960s. NASA initiated its CELSS Program ca. 1980 with testing focused on controlled environment production of some plants. Related tests with humans and crops were conducted at NASA’s Johnson Space Center in the 1990s. The European Space Agency MELiSSA Project began in the late 1980s and pursued ecological approaches for providing gas, water and materials recycling for space life support, and later expanded to include plant testing.As a result of these and other (Japan, Canada, China) studies for space agriculture novel technologies and fi ndings have been produced. The theme of agriculture for space has contributed to, and benefi ted from terrestrial, controlled environment agriculture and will continue doing so into the future.


Ключевые слова:

Waste recycling, Algal production, Controlled Environment Agriculture, Photosynthesis, Advanced Life-Support, Vertical Farming, Bioregenerative, Space crops, Agriculture for Space, Space.

Abstract: Agricultural systems for space have been discussed since the works of Tsiolkovsky in the early 20th century. Central to the concept is the use of photosynthetic organisms and light to generate oxygen and food. Research in the area started in 1950s and 60s through the works of Jack Myers and others, who studied algae for O2 production and CO2 removal for the US Air Force and NASA. Studies on algal production and controlled environment agriculture were also carried out by Russian researchers in Krasnoyarsk, beginning in 1960s. NASA initiated its CELSS Program ca. 1980 with testing focused on controlled environment production of some plants. Related tests with humans and crops were conducted at NASA’s Johnson Space Center in the 1990s. The European Space Agency MELiSSA Project began in the late 1980s and pursued ecological approaches for providing gas, water and materials recycling for space life support, and later expanded to include plant testing.As a result of these and other (Japan, Canada, China) studies for space agriculture novel technologies and findings have been produced. The theme of agriculture for space has contributed to, and benefited from terrestrial, controlled environment agriculture and will continue doing so into the future.


Keywords:

Waste recycling, Algal production, Controlled Environment Agriculture, Photosynthesis, Advanced Life-Support, Vertical Farming, Bioregenerative, Space crops, Agriculture for Space, Space


Эта статья может быть бесплатно загружена в формате PDF для чтения. Обращаем ваше внимание на необходимость соблюдения авторских прав, указания библиографической ссылки на статью при цитировании.

Скачать статью

Библиография
1. Tolley-Henry, L. and C.D. Raper Jr. 1986. Utilization of ammonium as a nitrogen source. Effects of ambient acidity on growth and nitrogen accumulation by soybean. Plant Physiol., 82, 54-60
2. Tikhomirova N.A., S.A. Ushakova, N.P. Kovaleva, I.V. Gribovskaya, and A.A. Tikhomirov. 2005. Influence of high concentrations of mineral salts on production process and NaCl accumulation by Salicornia europaea plants as a constituent of the LSS phototroph link. Adv. Space Res., 35, 1589-1593
3. Tikhomirov А.А., S.А. Ushakova, N.S. Manukovsky, G.М. Lisovsky, Yu. А. Kudenko, Kovalev, I.V. Gribovskaya, L.S. Tirranen, I.G. Zolotukhin, J.B. Gros, Ch. Lasseur. 2003. Synthesis of biomass and utilization of plants wastes in a physical model of biological life-support system. Acta Astronautica, 53, 249-257
4. Tibbitts, T.W. and D.K. Alford. 1982. Controlled ecological life support system. Use of higher plants. NASA Conf. Publ., 2231
5. Tennessen, D.J., R.L. Singsaas, and T.D. Sharkey. 1994. Lightemitting diodes as a light source for photosynthesis research. Photosynthesis Research, 39, 85-92
6. Taub, R.B. 1974. Closed ecological systems. In: R.F. Johnston, P.W. Frank, and C.D. Michener (eds.) Annual Review of Ecology and Systematics. Annual Reviews Inc., Palo Alto, CA. pp. 139-160
7. Tang, Y. S. Guo, W. Dong, L. Qin, W. Ai, and S. Lin. 2010. Effects of long-term low atmospheric pressure on gas exchange and growth of lettuce. Adv. Space Res., 46, 751-760
8. Tani, A., Y. Kitaya, M. Kiyota, I. Aiga, and K. Nitta. 1996. Problems related to plant cultivation in a closed system. Life Support and Biosphere Sci., 3, 129-140
9. Tako, Y., R. Arai, S. Tsuga, O., Komatsubara, T. Masuda, S. Nozoe, and K. Nitta. 2010. CEEF: Closed Ecology Experiment Facilities. Gravitation and Space Biol., 23(2), 13-24
10. Tako, Y. S. Tsuga, T. Tani, R. Arai, O. Komatsubara, and M. Shinohara. 2008. On-week habitation of two humans in an airtight facility with two goats and 23 crops—Analysis of carbon, oxygen, and water circulation. Adv. Space Res., 41, 714-724
11. Tako, Y., R. Arai, K. Otsubo, and K. Nitta. 2001. Integration of sequential cultivation of main crops and gas and water processing subsystems using closed ecology experiment facility. SAE Technical Paper, 2001-01-2133
12. Sytchev, V.N., M.A. Levinskikh, S.A. Gostimsky, G.E. Bingham, and I.G. Podolsky. 2007. Spaceflight effects on consecutive generations of peas grown onboard the Russian segment of the International Space Station. Acta Astronautica, 60, 426-432
13. Sytchev, V.N., E.Ya. Shepelev, G.I. Meleshhko, T.S. Gurieva, M.A. Levinskikh, I.G. Podolshy, O.A. Dadsheva, and V.V. Popov. 2001. Main characteristics of biological components of developing life support system observed during experiment about orbital complex MIR. Adv. Space Res., 27(9), 1529-1534
14. Sugimoto, M. Y. Oono, O. Gusev, T. Matsumoto, T. Yazawa, M. A. Levinshkikh, V.N. Sychev, G.E. Bingham, R. Wheeler and M. Hummerick. 2014. Genome-wide expression analysis of reactive oxygen species gene network in mizuna plants grown in long-term spaceflight. BMC Plant Biology, 2014, 14, 4
15. Stutte, G.W., O. Monje, G.D. Goins, and B.C. Tripathy. 2005. Microgravity effects on thylakoid, leaf, and whole canopy photosynthesis of dwarf wheat. Planta, 223, 46-56
16. Subbarao, G.V., R.M. Wheeler, and G.W. Stutte. 2000. Feasibility of substituting sodium for potassium in crop plants for advanced life support systems. Life Sup. Biosphere Sci., 7, 225-232
17. Stutte, G.W., C.L. Mackowiak, N.C. Yorio, and R.M. Wheeler. 1999. Theoretical and practical considerations of staggered crop production in a BLSS. Life Support Biosphere Sci., 6, 287-291
18. Strayer, R.F., M.P. Alazraki, N. Yorio, and B.W. Finger. 1998. Bioprocessing wheat residues to recycle plant nutrients to the JSC variable pressure growth chamber during the L/MLSTP Phase III test. SAE Tech. Paper Series 981706
19. Stasiak, M., D. Gidzinski, M. Jordan, and M. Dixon. 2012. Crop selection for advanced life support systems in the ESA MELiSSA program: Durum wheat (Triticum turgidum var. durum). Adv. Space Res., 49, 1684-1690
20. Stasiak, M.A., R. Cote, M. Dixon, and B. Grodzinski. 1998. Increasing plant productivity in closed environments with inner canopy illumination. Life Supp. Biosph. Sci., 5, 175-182
21. Stasiak, M., G. Waters, Y. Zheng, B. Grodzinski and M. Dixon. 2003. Integrated multicropping of beet and lettuce and its effect on atmospheric stability. SAE Technical Paper, 2003-01-2357
22. Sorokin, C. and J. Myers. 1953. A high-temperature strain of Chlorella. Science, 117, 330-331
23. Schwartzkopf, S.H. and R.L. Mancinelli. 1991. Germination and growth of wheat in simulated Martian atmospheres. Acta Astronautica, 25(4), 245-247
24. Schwartzkopf, S.H. 1985. A non-destructive method for monitoring plant growth. HortSci., 20, 432-434
25. Schuerger, A.C., C.S. Brown, and E.C. Stryjewski. 1997. Anatomical features of pepper plants (Capsicum annuum L.) grown under red light-emitting diodes supplemented with blue or far-red light. Ann. Botany, 79, 273-282
26. Schubert, D. D. Quantius, J. Hauslage, L. Glasgow, F. Schröder, and M. Dorn. 2011. Advanced Greenhouse Modules for use within Planetary Habitats. 41st ICES, Portland, Oregon AIAA 2011-5166
27. Salisbury, F.B., W. F. Campbell, J. G. Carman, G. E. Bingham, D. L. Bubenheim, B. Yendler, V. Sytchev, M. A. Levinskikh, I. Ivanova, L. Chernova and I. Podolsky. 2003. Plant growth during the greenhouse II experiment on the Mir orbital station. Adv. Space Res., 31(1), 221-227
28. Salisbury, F.B., J.E. Gitelson, and G.M. Lisovsky. 1997. Bios-3: Siberian experiments in bioregenerative life support. BioScience, 47, 575-585
29. Salisbury, F.B. 1991. Lunar farming: Achieving maximum yield for the exploration of space. HortScience, 26(7), 827-833
30. Sadler, P.D. and G.A. Giacomelli. 2002. Mars inflatable greenhouse analog. Life Support Biosphere Sci., 8, 115-123
31. Sadler, P. 1995. The Antarctic horticultural project. Proc. Hydroponic Soc. Amer. 16th Ann. Conf. on Hydroponics, Tucson, AZ. pp. 95-107
32. Rygalov, V.Y., P. A. Fowler, R.M. Wheeler, and R.A. Bucklin. 2004. Water cycle and its management for plant habitats at reduced pressures. Habitation, 10(1), 49-59
33. Rossignoli, S. and Aero Sekur Inc. 2016. Co-organizer and sponsor of AgroSpace Workshops from 2006-2016: http://www.agrospaceconference.com/
34. Resh, H.M. 1989. Hydroponic food production. 4th Edition. Woodbridge Press Publ. Comp., Santa Barbara CA. pp. 462
35. Ren, J., S. Guo, C. Xu, C. Yang, W. Ai, Y. Tang, and L. Qin. 2014. Effects of different carbon dioxide and LED lighting levels on the anti-oxidative capabilities of Gynura bicolor DC. Adv. Space Res., 53, 353-361
36. Qin, L., S. Guo, W. Ai, Y. Tang, Q. Cheng, G. Chen. 2013. Effect of salt stress on growth and physiology in amaranth and lettuce: Implications for bioregenerative life support system. Adv. Space Res., 51, 476-482
37. Qin, L., S. Guo, W. Ai, and Y. Tang. 2008. Selection of candidate salad vegetables for controlled ecological life support system. Advances in Space Research, 41, 768-772
38. Prince, R.P. and W.M. Knott. 1989. CELSS Breadboard Project at the Kennedy Space Center. In D.W. Ming and D.L. Henninger (eds.). Lunar Base Agriculture: Soils for Plant Growth. Amer. Soc. Of Agronomy, Madison, WI, USA. pp. 155-163
39. Porter M.A. and B. Grodzinski. 1985. CO2 enrichment of protected crops. Horticultural Reviews, 7, 345-398
40. Prince, R.P. and J.W. Bartok. 1978. Plant spacing for controlled environment plant growth. Trans. Amer. Soc. Agric. Eng., 21, 332-336
41. Paul, A-L., A.C. Schuerger, M.P. Popp, J.T. Richards, M.S. Manak, R.J. and Ferl. 2004. Hypobaric biology: Arabidopsis gene expression at low atmospheric pressure. Plant Physiol., 134, 215-223
42. Patterson, R.L., G.A. Giacomelli, and P.A. Sadler. 2008. Resource and production model for the South Pole food growth chamber. SAE Technical Paper, 2008-01-2011
43. Paradiso, R., V. De Micco, R. Buonomo, G. Aronne, G. Barbier, and S. De Pascale. 2014. Soilless cultivation of soybean for Bioregenerative Life-Support Systems: a literature review and the experience of the MELiSSA Project – food characterization Phase I. Plant Biology, 16, (Suppl. 1), 69–78
44. Paradiso, R., R. Buonomo, V. De Micco, G. Aronne, M. Palermo, G. Barbieri, and S. De Pascale. 2012. Soybean cultivar selection for bioregenerative life support systems (BLSSs) – Hydroponic cultivation. Adv. Space Res., 50, 1501-1511
45. Ohler, T.A. and C.A. Mitchell. 1996. Identifying yield-optimizing environments for two cowpea-breeding lines by manipulating photoperiod and harvest scenario. J. Amer. Soc. Hort. Sci., 121, 576-581
46. Nitta, K. and M. Yamashita. 1985. Concept study on the technology of CELSS. Earth-Orient. Applic. Space Technol., 5(3), 253-263
47. Nitta, K. K. Otsubo, and A. Ashida. 2000. Integration test project of CEEF—A test bed for closed ecological life support Systems Adv. Space Res., 26, 335-338
48. Nelson, M., W.F. Dempster, J.P. Allen, S. Silverston, A. Alling, and M. van Thillo. 2008. Cowpeas and pinto beans: Performance and yield of candidate space crops in the laboratory biosphere closed ecological system. Adv. Space Res. 41, 748-753
49. Nelson, M., W.F. Dempster, S. Silverstone, A. Alling, J.P. Allen and M. van Thillo. 2005. Crop yield and light/energy efficiency in a closed ecological system: Laboratory biosphere experiments with wheat and sweet potato. Advances in Space Research, 35(9), 1539-1543
50. Myers, J. 1954. Basic remarks on the use of plants as biological gas exchangers in a closed system. J. Aviation Med., 25, 407-411
51. Nakamura, T., A.D. van Pelt, N.C. Yorio, A.E. Drysdale, R.M. Wheeler, and J.C. Sager. 2009. Transmission and distribution of photosynthetically active radiation (PAR) from solar and electric light sources. Habitation, 12(1), 103-117
52. Mortley, E.G., C.K. Bonsi, P.A. Loretan, W.A. Hill, and C.E. Morris. 2000. High relative humidity increases yield, harvest index, flowering, and gynophore growth of hydroponically grown peanut plants. HortSci., 35, 46-48
53. Mortley, D., J. Hill, P. Loretan, C. Bonsi, and W. Hill. 1996. Elevated carbon dioxide influences yield and photosynthetic responses of hydroponically-grown sweetpotato. Acta Hort., 440, 31-36
54. Mortley, D.G., C.K. Bonsi, W.A. Hill, P.A. Loretan, and C.E. Morris. 1993. Irradiance and nitrogen to potassium ratio influences sweetpotato yield in nutrient film technique. Crop Science, 33, 782-784
55. Mortley, D.G., C.K. Bonsi, P.A. Loretan, C.E. Morris, W.A. Hill, and C.R. Ogbuehi. 1991. Evaluation of sweet potato genotypes for adaptability to hydroponic systems. Crop Sci., 31, 845-847
56. Morrow, R.C. 2008. LED lighting in horticulture. HortScience, 43(7), 1947-1950
57. Morrow, R.C., W.R. Dinauer, R.J. Bula, and T.W. Tibbitts. 1993. The ASTROCULTURE™-1 flight experiment: Pressure control of the WCSAR porous tube nutrient delivery system. SAE Technical Paper Series, No. 932292
58. Monje, O., G. Stutte, and D. Chapman. 2005. Microgravity does not alter plant stand gas exchange of wheat at moderate light levels and saturating CO2 concentration. Planta, 222, 336-345
59. Monje, O., and B. Bugbee. 1998. Adaptation to high CO2 concentration in an optimal environment: Radiation capture, canopy quantum yield and carbon use efficiency. Plant Cell Environ., 21, 315-324
60. Miller, R.L. and C.H. Ward. 1966. Algal bioregenerative systems. In: E. Kammermeyer (ed.) Atmosphere in space cabins and closed environments. Appleton-Century-Croft Pub., New York, pp. 186-221
61. Mitchell, C.A., M.P. Dzakovich, C. Gomez, R. Lopez, J.F. Burr, R. Hernández, C. Kubota, C.J. Currey, Q. Meng, E. S. Runkle, C. M. Bourget, R.C. Morrow, and A.J. Both. 2015. Light-emitting diodes in horticulture. Horticultural Reviews, Volume 43, 1-87
62. Mergeay, M., W. Verstraete, G. Dubertet, M. Lefort-Tran, C. Chipaux, and R. Binot. 1987. MELISSA- A microorganisms-based model for CELSS develop. Proceedings 3rd European Symp. Space Thermal Control and Life Support Systems, Noordwijk, ESA SP-288. pp. 65-68
63. McAvoy, R.J., H.W. Janes, B.L. Godfriaux, M. Secks, D. Duchai, and W.K. Wittman. 1989. The effect of total available photosynthetic photon flux on single truss tomato growth and production. J. Hort. Science, 64, 331-338
64. Matthern, R.O. and R.B. Koch. 1964. Developing an unconventional food, algae, by continuous culture under high light intensity. Food Technol., 18, 58-65
65. Masuda, T., T. Ogasawara, E. Harashima, Y. Tako, and K. Nitta. 2005. Evaluation and implementation of an advanced life support (ALS) menu for Closed ecology Experiment Facilities (CEEF). Eco-Engineering, 17(1), 55-60
66. Massa, G.E., N.F. Dufour, J.A. Carver, M.E. Hummerick, R.M. Wheeler, R.C. Morrow, T.M. Smith. 2016. VEG-01: Veggie hardware validation testing on the International Space Station. Open Agricul. (in press)
67. Massa, G.D, H.H. Kim, R.M. Wheeler, and C.A. Mitchell 2008. Plant productivity in response to LED lighting. HortScience, 43(7), 1951-1956
68. Mansell, R.L. 1968. Effects of prolonged reduced pressure on the growth and nitrogen content of turnip (Brassica rapa L.). SAM-TR-68-100. School of Aerospace Medicine, Brooks Air Force Base, Texas
69. Mackowiak, C.L, R.M. Wheeler, G.W. Stutte, N.C. Yorio, and L.M. Ruffe. 1998. A recirculating hydroponic system for studying peanut (Arachis hypogaea L.). HortScience, 33, 650-651
70. MacElroy, R.D. and J. Bredt. 1985. Current concepts and future directions of CELSS. Adv. Space Res., 4(12), 221-230
71. MacElroy, R.D., M. Kliss, and C. Straight. 1992. Life support systems for Mars transit. Adv. Space Res., 12(5), 159-166
72. Lobascio, C., M. Lamantea, S. Palumberi, V. Cotronei, B. Negri, S. De Pascale, A. Maggio, M. Maffei, and M. Fote. 2008. Functional architecture and development of the CAB bioregenerative system. SAE Technical Paper, 2008-01-2012
73. Lobascio, C., M. Lamantea, M.A. Perino, L. Bertaggia, V. Bornicsacci, and F. Piccolo. 2006. Plant facilities for inflatable habitats. ICES Tech. Paper, 2006-01-2214
74. Lisovsky, G.M., J.I. Gitelson, M.P. Shilenko, I.V. Brivovskaya, and I.M Trubachev. 1997. Direct utilization of human liquid wastes by plants in a closed ecosystem. Adv. Space Res., 20(10), 1801-1804
75. Loader, C.A., J.L. Garland, L.H. Levine, K.L. Cook, C.L. Mackowiak, and H.R. Vivenzio. 1999. Direct recycling of human hygiene water into hydroponic plant growth systems. Life Support Biosphere Sci., 6, 141-152
76. Levine, L.H., P.A. Bisbee, T.A. Richards, M.N. Birmele, R.L. Prior, M. Perchonok, M. Dixon, N.C. Yorio, G.W. Stutte, and R.M. Wheeler. 2008. Quality characteristics of radish grown under reduced atmospheric pressure. Adv. Space Res., 41, 754-762
77. Levinskikh, M.A., V.N. Sychev, T.A. Derendyaeva, O.B. Signalova, F.B. Salisbury, W.F. Campbell, G.E. Bingham, D.L. Bubenheim, and G. Jahns. 2000. Analysis of the spaceflight effects on growth and development of Super Dwarf wheat grown on the space station Mir. J. Plant Physiol., 156, 522-529
78. Ley, W. 1948. Rockets and space travel. The future of flight beyond the stratosphere. The Viking Press, New York, NY, USA. pp. 374
79. Lenk, S., L. Chaerle, E.E. Pfündel, G. Langsdorf, D. Hagenbeek, H.K. Lichtenthaler, D. Van Der Straeten, and C. Buschmann. 2007. Multispectral fluorescence and reflectance imaging at the leaf level and its possible applications. J. Experimental Botany, 58, 807-814
80. Law, J., M, Van Baalen, M. Foy, S.S. Mason, C. Mendez, M.L. Wear, V.E. Meyers, and D. Alexander. 2014. Relationship between carbon dioxide levels and reported headaches on the International Space Station. J. Occupational Environ. Medicine, 56(5), 477-483
81. Lange, K, A.T. Perka, B.E. Duffield and F.F. Jeng 2005. Bounding the spacecraft atmosphere design space for future exploration missions. NASA Contractor Report CR-2005-213689
82. Lasseur, C., W. Verstraete, J.B. Gros, G. Dubertret, and F. Rogalla. 1996. MELISSA: a potential experiment for a precursor mission to the Moon. Adv. Space Res., 18, 111-117
83. Krall, A.R. and B. Kok. 1960. Studies on algal gas exchanges with reference to space flight. Developments in Industrial Microbiology, 1, 33-44
84. Krauss, R. 1962. Mass culture of algae for food and other organic compounds. Amer. J. Botany, 49, 425-435
85. Knight, S.L. and C.A. Mitchell. 1988. Effects of incandescent radiation on photosynthesis, growth rate and yield of Waldmann’s Green’ leaf lettuce . Scientia Horticulturae, 35, 37-49
86. Kliss, M., A.G. Heyenga, A. Hoehn and L.S. Stodieck. 2000. Recent advances in technologies required for a “Salad Machine”. Adv. Space Res., 26(2), 263-269
87. Kliss, M. and R.D. MacElroy. 1990. Salad machine: A vegetable production unit for long duration space missions. SAE Tech. Paper 901280. Williamsburg, VA, USA. July 1990
88. Klassen, S.P. and B. Bubgee. 2004. Ethylene synthesis and sensitivity in crop plants. HortScience, 39, 1546-1552
89. Kitaya, Y. H. Hirai, X. Wei, A.F.M.S. Islam, and M. Yamamoto. 2008. Growth of sweetpotato cultured in the newly designed hydroponic system for space farming. Adv. Space Res., 41, 730-735
90. Kitaya, Y. and H. Hirai. 2008. Effects of lighting and air movement on temperatures in reproductive organs of plants in a closed plant growth facility. Adv. Space Res., 41, 763-676
91. Kitaya, Y. M. Kawai, J. Tsuruyama, H. Takahashi, A. Tani, E. Goto, T. Saito, M. Kiyota. 2003. The effect of gravity on surface temperature of plant leaves. Plant, Cell Environment, 26, 497-503
92. Kim, H-H., J. Norikane, R.M. Wheeler, J.C. Sager, and N.C. Yorio. 2007. Electric lighting considerations for crop production in space. Acta Horticulturae, 761, 193-202
93. Kim, H-H., G.D. Goins, R.M. Wheeler, and J.C. Sager. 2004. Stomatal of lettuce grown under or exposed to different light qualities. Annals of Botany, 94, 691-697
94. Kibe, S. and K. Suzuki. 1997. Japan’s activities on CELSS in space. In: P. M. Bainum, G.L. May, M. Nagatomo, K.T. Uesugi, F. Bingchen, and Z. Hui (eds.), Space Cooperation into the 21st Century (7th ISCOPS) AAS 97-459, 96, 605-125
95. Katayama, N., Y. Ishikawa, M. Takaoki, M. Yamashita, S. Nakayama, K. Kiguchi, R. Kok, H. Wada, J. Mitsuhashi,. 2008. Entomophagy: A key to space agriculture. Adv. Space Res., 41, 701-705
96. Karel, M., A.R. Kamarel, and Z. Nakhost. 1985. Utilization of non-conventional systems for conversion of biomass to food components. Potential for utilization of algae in engineered foods. NASA CR-176257
97. Kacira, M., G. Giacomelli, L. Patterson, R. Furfaro, P. Sadler, G. Boscheri, C. Lobascio, M. Lamantea, R. Wheeler, and S. Rossignoli. 2012. System dynamics and performance factors of a lunar greenhouse prototype bioregenerative life support system. Acta Hort., 952, 575-582
98. Jasoni, R., C. Kane, C. Green, E. Peffley, D. Tissue, L. Thompson, P. Payton, and P. W. Paré. 2004. Altered leaf and root emissions from onion (Allium cepa L.) grown under elevated CO2 conditions. Environment and Experimental Botany., 51, 273-280
99. Iwabuchi, K. and K. Kurata. 2003. Short-term and long-term effects of low total pressure on gas exchange rates of spinach. Adv. Space Res., 31(1), 241-244
100. Iwabuchi, K., E. Goto, and T. Takakura. 1996. Germination and growth of spinach under hypobaric conditions. Environ. Control in Biol., 34, 169-178
101. Hummerick, M.E., J. Garland, G. Bingham, V.N. Sychev, and I.G. Podolsky. 2010. Microbiological analysis of Lada Vegetable Production Units (VPU) to define critical control points and procedures to ensure the safety of space grown vegetables. Amer. Inst. Aeronautics Astronautics, 40th ICES meeting, Barcelona, Spain, July 11-15, 2010. AIAA-2010-6253
102. Hoff, J.E., J.M. Howe, and C.A. Mitchell. 1982. Nutritional and cultural aspects of plant species selection for a regenerative life Support system. Report to NASA Ames Research Center, NSG2401 and NSG 2404
103. Heinse, R., S.B. Jones, M. Tuller, G.E. Bingham, I. Podolskiy, and D. Or. 2009. Providing optimal root-zone fluid fluxes: Effects of hysteresis on capillary-dominated water distributions in reduced gravity. SAE Technical Paper, 2009-01-2360
104. Heinse, R., S.B. Jones, S.L. Steinberg, M. Tuller, and D. Or. 2007. Measurements and modeling of variable gravity effects on water distribution and flow in unsaturated porous media. Vadose Zone J., 6, 713–724
105. He, C., R.T. Davies, and R.E. Lacey. 2009. Ethylene reduces gas exchange and growth of lettuce plants under hypobaric and normal atmospheric conditions. Physiol. Plant,135, 258-271
106. He, C., F.R. Davies, and R.E. Lacey. 2007. Separating the effects of hypobaria and hypoxia on lettuce: growth and gas exchange. Physiologia Plantarum, 131, 226-240
107. Guo, S., X. Liu, W. Ai, Y. Tang, J. Zhu,, X. Wang, M. Wei, L. Qin, and Y. Yang. 2008. Development of an improved ground-based prototyped of space plant-growing facility. Adv. Space Res., 41, 736-741
108. Guerra, D., A.J. Anderson, and F.B. Salisbury. 1985. Reduced phenylalanine ammonia-lyase and tyrosine ammonia-lyase activities and lignin synthesis in wheat grown under low-pressure sodium lamps. Plant Physiol., 78, 126-130
109. Guerra, D., A.J. Anderson, and F.B. Salisbury. 1985. Reduced phenylalanine ammonia-lyase and tyrosine ammonia-lyase activities and lignin synthesis in wheat grown under low-pressure sodium lamps. Plant Physiol., 78, 126-130
110. Grotenhuis, T.P. and B. Bugbee. 1997. Super-optimal CO2 reduces seed yield but not vegetative growth in wheat. Crop Science, 37, 1215-1222
111. Gros, J.B., L. Poughon, C. Lasseur, and A. A. Tikhomirov. 2004. Recycling efficiencies of C, H, O, N, S, and P elements in a biological life support system based on microorganisms and higher plants Advances in Space Research, 31, 195-199
112. Greg, P. 2006. Across the zodiac. BiblioBazaar ISBN-1-4264-4026-X (originally written in 1880)
113. Grodzinski, B. 1992. Plant nutrition and growth regulation by CO2 enrichment. BioScience, 42, 517-525
114. Goto, E. 2012. Plant production in a closed plant factory with artificial lighting. Acta Hort., 956, 37-50
115. Goto, E., Ohta, H., Iwabuchi, K., Takakura, T. 1996. Measurement of net photosynthetic and transpiration rates of spinach and maize plants under hypobaric conditions. J. Agric. Meteorol., 52, 117–123
116. Golueke, C.G. and W.J. Oswald. 1964. Role of plants in closed systems. Ann. Rev. Plant Physiol., 15, 387-408
117. Goldman, K.R. and C.A. Mitchell. 1999. Transfer from long to short photoperiods affects production efficiency of day-neutral rice. HortScience, 34, 875-877
118. Goins, G.D., L.M. Ruffe, N.A. Cranston, N.C. Yorio, R.M. Wheeler, and J.C. Sager. 2001. Salad crop production under different wavelengths of red light-emitting diodes (LEDs). Soc. Automotive Eng. Tech. Paper, 2001-01-2422
119. Goins, G.D., N.C. Yorio, M.M. Sanwo, and C.S. Brown. 1997. Photomorphogenesis, photosynthesis, and seed yield of wheat plants grown under red light-emitting diodes (LEDs) with and without supplemental blue lighting. J. Exp. Bot., 48, 1407-1413
120. Godia, F., J. Albiol, J. Perez, N. Creus, F. Cabello, A. Montras, A. Maso, and Ch. Lasseur. 2004. The MELISSA pilot plant facility as an integration test-bed for advanced life support systems. Advances in Space Research, 34, 1483-1493
121. Gitelson, J.I. and Yu. N. Okladnikov. 1994. Man as a component of a closed ecological life support systems. Life Support Biosphere Sci., 1, 73-81
122. Gitelson, J.I., I.A. Terskov, B.G. Kovrov, G.M. Lisoviskii, Yu. N. Okladnikov, F. Ya. Sid’ko, I.N. Tuubachev, M.P. Shilenko, S.S. Alekseev, I.M. Pan’kova, and L.S. Tirranen. 1989. Long-term experiments on man’s stay in biological life-support system. Adv. Space Res., 9(8), 65-71
123. Gitelson, J.I., I.A. Terskov, B.G. Kovrov, R. Ya. Sidko, G.M. Lisovsky, Yu. N. Okladnikov, V.N. Belyanin, I.N. Trubachov, and M.S. Rerberg. 1976. Life support system with autonomous control employing plant photosynthesis. Acta Astronautica, 3, 633-650
124. Gitelson, I.I., B.G. Kovrov, G.M. Lisovsky, Y.N. Okladikova, M.S. Rerberg, F.Y. Sidko, and I. A. Terskov. 1975. Toxic gases emitted by Chlorella. In: Problems in Space Biology
125. Gianfagna, T.J., L. Logendra, E.F. Durner, and H.W. Janes. 1998. Improving tomato harvest index by controlling crop height and side shoot production. Life Support and Biosphere Science, 5, 255-262
126. Gerbaud, A. M. Andre, and C. Richaud. 1988. Gas exchange and nutrition patterns during the life cycle of an artificial wheat crop. Physiol. Plant., 73, 471-478
127. Gazenko, O.G. 1967. Development of biology in the USSR. In: Soviet Science and Technology for 50 years. Nauka Press, Moscow (In Russian; citation from Salisbury et al., 1997).
128. Fu, Y. L. Li, B. Xie, C. Dong, M. Wang, B. Jia, L. Sho, Y. Dong, S. Deng, H. Liu, G. Liu, B. Liu, D. Hu, and H. Liu. 2016. How to establish a bioregenerative life support system for long-term crewed missions to the Moon and Mars. Astrobiology (In Press)
129. Frantz, J.M., R.J. Joly, and C.A. Mitchell. 2000. Intracanopy lighting influences radiation capture, productivity, and leaf senescence in cowpea canopies. J. Amer. Soc. Hort. Sci., 125, 694-701
130. Fowler, P.A., R.M. Wheeler, R.A. Bucklin, and K.A. Corey. 2000. Low pressure greenhouse concepts for Mars. In: R.M. Wheeler and C. Martin-Brennan (eds.) Mars greenhouses: Concept and Challenges. NASA Tech. Mem. 208577
131. Fong, F. and E.A. Funkhouser. 1982. Air pollutant production by algal cell cultures. NASA Cooperative Agreement NCC 2-102
132. Eley, J.H. and J. Myers. 1964. Study of a photosynthetic gas exchanger. A quantitative repetition of the Priestley experiment. Tex. J. Sci., 16, 296-333
133. Edeen, M.A., J.S. Dominick, D.J. Barta and N.J.C Packham. 1996. Control of air revitalization using plants: Results of the early human testing initiative Phase I Test. SAE Tech. Paper Series, No. 961522
134. Dreschel, T.W. and J.C. Sager. 1989. Control of water and nutrient using a porous tube: A method for growth plants in space. HortScience, 24, 944-947
135. Dougher, T.A.O. and B.G. Bugbee. 2001. Differences in the response of wheat, soybean and lettuce to reduced blue radiation. Photochem. Photobiol., 73, 199-207
136. Dong, C., Y. Fu, G. Liu, and H. Liu. 2014b. Low light intensity effects on the growth, photosynthetic characteristic, antioxidant capacity, yield and quality of wheat (Triticum aestivum L.) at different growth states in BLSS. Adv. Space Res., 53, 1557-1566
137. Dixon, M., D. Schmitt. 2001. A Canadian Vision for Advanced Life Support. The Canadian Journal of Space Exploration., 1,1, 6-12
138. Dong, C., Y. Fu, G. Liu, and H. Liu. 2014a. Growth photosynthetic characteristics, antioxidant capacity and biomass yield and quality of wheat (Triticum aestivum L.) exposed to LED light sources with different spectra combinations. J. Agronomy and Crop Sci., 200, 219-230
139. De Micco, V. R. Buonomo, R. Paradiso, S. De Pascale, and G. Aronne. 2012. Soybean cultivar selection for Bioregenerative Life Support Systems (BLSS) – Theoretical selection. Adv. Space Res., 49, 1415-1421
140. Davis, N. 1985. Controlled-environment agriculture – Past, present, and future. Food Technology, 39, 124-126
141. Daunicht, H.-J. and H.-J. Brinkjans. 1992. Gas exchange and growth of plants under reduced air pressure. Advances in Space Research, 12(5), 107-114
142. Croxdale, J., M. Cook, T.W. Tibbitts, C.S. Brown, and R.M. Wheeler. 1997. Structure of potato tubers formed during spaceflight. J. Exp. Bot., 48, 2037-2043
143. Corey, K.A., D.J. Barta, and R.M. Wheeler. 2002. Toward Martian agriculture: Responses of plants to hypobaria. 2002. Life Sup. Biosphere Sci., 8,103-114
144. Cuello, J.D., D. Jack, E. Ono, and T. Nakamura. 2000. Supplemental terrestrial solar lighting for an experimental subterranean biomass production chamber. Soc. Automotive Eng. Tech. Paper, 2000-01-2428
145. Corey, K.A., D.J. Barta, and D.L. Henninger. 1997. Photosynthesis and respiration of a wheat stand at reduced atmospheric pressure and reduced oxygen. Adv. Space Res., 20(10), 1869-1877
146. Cook, M.E., J.L. Croxdale, T.W. Tibbitts, C.S. Brown, and R.M. Wheeler. 1998. Development and growth of potato tubers in microgravity. Advances in Space Research, 21,1103-1110
147. Chamberlain, C.P., M.A. Stasiak and M.A. Dixon. 2003. Response of plant water status to reduced atmospheric pressure. SAE Technical Paper Series, 2003-01-2677
148. Chaerle, L., D. Hagenbeek, X. Vanrobaeys, and D. Van Der Straeten. 2007. Early detection of nutrient and biotic stress in Phaseolus vulgaris. Intl. J. Remote Sensing, 28, 3479-3492
149. Cao, W. and T.W. Tibbitts. 1991. Potassium concentrations effect on growth, gas exchange, and mineral accumulation in potatoes. J. Plant Nutr., 14, 525-537
150. Cao, W. and T.W. Tibbitts. 1994. Phasic temperature change patterns affect growth and tuberization in potatoes. J. Amer. Soc. Hort. Sci., 119, 775-778
151. Cathey, H.M. and L.E. Campbell. 1980. Light and lighting systems for horticultural plants. Horticultural Reviews, 2, 491-537
152. Burg, S.P. and E.A. Burg. 1966. Fruit storage at subatmospheric pressures. Science, 153, 314-315
153. Bula, R.J., R.C. Morrow, T.W. Tibbitts, D.J. Barta, R.W. Ignatius, and T.S. Martin. 1991. Light-emitting diodes as a radiation source for plants. HortScience, 26, 203-205
154. Bucklin, R.A., P.A. Fowler, V.Y Rygalov, R.M. Wheeler, Y. Mu, L. Hublitz, and E.G. Wilkerson. 2004. Greenhouse design for the Mars environment: Development of a prototype deployable dome. Acta Horticulturae, 659, 127-134
155. Bugbee, B.G 1995. Nutrient management in recirculating hydroponic culture. 1995 Proceedings from the Hydroponic Society of America, pp 15-30
156. Bugbee, B. and O. Monje. 1992. The limits of crop productivity. BioScience, 42, 494-502
157. Bugbee, B., B. Spanarkel, S. Johnson, O. Monje, and G. Koerner. 1994. CO2 crop growth enhancement and toxicity in wheat and rice. Adv. Space Res., 14, 257-267
158. Bubgee, B.G. and F.B. Salisbury. 1988. Exploring the limits of crop productivity. Photosynthetic efficiency of wheat in high irradiance environments. Plant Physiol., 88, 869-878
159. Bonsi, C.K., P.A. Loretan, W.A. Hill, and D.G. Mortley. 1992. Response of sweetpotatoes to continuous light. HortSci., 27, 471
160. Brown, C.S., T.W. Tibbitts, J.G. Croxdale, and R.M. Wheeler. 1997. Potato tuber formation in the spaceflight environment. J. Life Support and Biosphere Sci., 4, 71-76
161. Boeing Comp. 1962. Investigations of selected higher plants as gas exchange mechanism for closed ecological systems. In: Biologistics for Space Systems Symposium, May 1962. AMRL-TDR-62-116, Wright-Patterson Air Force Base, Ohio, USA
162. Bonsi, C.K., D.G. Mortley, P.A. Loretan, and W.A. Hill. 1994. Temperature and light effects of sweetpotatoes grown hydroponically. Acta Hort., 361, 527-529
163. Bingham, G.E., T.S. Topham, A. Taylor, I.G. Podolshy, M.A. Levinskikh, and V.N. Sychev. 2003. Lada: ISS plant growth technology checkout. SAE Technical Paper, 2003-01-2613
164. Bingham, G.E., Levinskikh, M.A., Sytchev V.N., and I.G. Podolsky. 2000. Effects of gravity on plant growth. J. Grav. Physiol., 7, 5-8
165. Bingham, G., F. Salisbury, W. Campbell, J. Carman, B.Y. Yendler, V. S. Sytchev, Y. B. Berkovich, M. A. Levinskikh and I. Podolsky. 1996. The spacelab-Mir-1 “Greenhouse-2” experiment. Adv. Space Res., 18, 225-232
166. Berkovich, Yu. A., S.O. Smolyanina, N.M. Krivobok, A.N. Erokhin, A.N. Agureev, and N.A. Shanturin. 2009. Vegetable production facility as a part of a closed life support system in a Russian Martian space flight scenario. Adv. Space Res., 44, 170–176
167. Berkovich, Yu.A., N.M. Krivobok, Yu.Ye. Sinyak, S.O. Smolyanina, Yu.I. Grigoriev, S.Yu. Romanov and A.S. Guissenberg. 2004. Developing a vitamin greenhouse for the life support system of the International Space Station and for future interplanetary missions. Advances in Space Research, 34(7), 1552-1557
168. Berkovich, Yu. A., N M. Krivobok, and Yu. E. Sinyak. 1998. Project of conveyer-type space greenhouse for cosmonauts’ supply with vitamin greenery. Adv. Space Res., 22(10), 1401-1405
169. Barta, D.J., J.M. Castillo, and R.E. Fortson. 1999. The biomass production system for the bioregenerative planetary life support systems test complex: Preliminary designs and considerations. SAE Technical, Paper 1999-01-2188
170. Batten, J.H., G.W. Stutte, and R.M. Wheeler 1995. Effect of crop development on biogenic emissions from plant populations grown in a closed plant growth chambers. Phytochem., 39, 1351-1357
171. Barta, D.J., J.M. Castillo, and R.E. Fortson. 1999. The biomass production system for the bioregenerative planetary life support systems test complex: Preliminary designs and considerations. SAE Technical Paper, 1999-01-2188
172. Barta, D.J. and K. Henderson. 1998. Performance of wheat for air revitalization and food production during the Lunar-Mars life support test project phase III test. SAE Technical Paper, Series 98104
173. Barta, D.J., T.W. Tibbitts, R.J. Bula, and R.C. Morrow. 1992. Evaluation of light emitting diodes characteristics for a space-based plant irradiation source. Adv. Space Res., 12(5), 141-149
174. Barnes, C. and B. Bugbee. 1992. Morphological responses of wheat to blue light. J. Plant Physiol., 139,339-342
175. Barta, D.J. and T.W. Tibbitts. 1991. Calcium localization in lettuce leaves with and without tipburn: Comparison of controlled environment and field grown plants. J. Amer. Soc. Hort. Sci., 116, 870-875
176. Bamsey, M., Graham, T., Thompson, C., Bertinstain, A., Scott, A., M. Dixon, University of Guelph, Canada. 2012. Ion-Specific nutrient management in closed systems: the necessity for ion-selective sensors in terrestrial and space-based agriculture and water management systems. Sensors, 12(10), 13349-13391
177. Bamsey, M. T. Graham, M. Stasiak, A. Berinstain, A. Scott, and T. Rondeau Vuk, and M. Dixon. 2009. Canadian advanced life support capacities and future directions. Advances in Space Research, 44, 151-161
178. Averner, M., M. Karel, and R. Radmer. 1984. Problems associated with using algae in bioregenerative life support systems. NASA Contractor Report 166615, Ames Research Center, Moffett Field, CA
179. Ashida, A and K. Nitta. 1995. Construction of CEEF (Closed Ecology experiment Facility) is just started. SAE Tech., Paper 951584
180. Avercheva, O., Yu,A. Berkovich, S. Smolyanina, E. Bassarskaya, S. Pogosyan, V. Ptushenko, A. Erokhin, T. Zhigalova. 2014. Biochemical, photosynthetic and productive parameters of Chinese cabbage grown under blue–red LED assembly designed for space agriculture. Adv. Space Res., 53, 1574-1581
181. Andre, M. and D. Massimino. 1992. Growth of plants at reduced pressures: Experiments in wheat—technological advantages and constraints. Adv. Space Res., 12(5), 97-106
182. Andre, M., F. Cote, A. Gerbaud, D. Massimino, J. Massimino, and C. Richaud. 1989. Effect of CO2 and O2 on development and fructification of wheat in closed systems. Adv. Space Res., 9(8),17-28
183. Alling, A., M. Van Thillo, W. Dempster, M. Nelson, S. Silverstone, and J. Allen. 2005. Lessons learned from Biosphere 2 and laboratory biosphere closed systems experiment for the Mars on Earth project. Biological Sci. in Space, 19(4), 250-260
184. Tripathy, B.C. and C.S. Brown. 1995. Root-shoot interaction in the greening of wheat seedlings grown under red light. Plant Physiol., 107, 407-411
185. Tsiolkovsky, K.E. 1975. Study of outer space by reaction devices. In: NASA Technical Translation NASA TT F-15571 of “Issledovaniye mirovykh prostranstv reaktivnymi priborami”, Mashinotroyeniye Press, Moscow, 1967
186. Wada, H., M. Yamashita, N. Katayama, J. Mitsuhashi, H. Takeda, and H. Hashimoto. 2009. Agriculture on Earth and on Mars. In: J .H. Denis and P.D. Aldridge (eds.), Space Exploration Research, pp. 481-498
187. Wang, M., B. Xie, Y. Fu, C. Dong, L. Hui, L. Guanghui, and H. Liu. 2015a. Effects of different elevated CO2 concentrations on chlorophyll contents, gas exchange, water use efficiency, and PSII activity on C3 and C4 cereal crops in a closed artificial ecosystem. Photosynthesis Research, 126(2-3), 351-362
188. Wang, M., Y. Fu, and H. Liu. 2015b. Nutritional status and ion uptake response of Gynura bicolor DC between Porous-tube and traditional hydroponic growth systems. Acta Astronautica, 113, 13–21
189. Waters, G.R., A. Olabi, J.B. Hunter, M.A. Dixon and C. Lasseur. 2002. Bioregenerative food system cost based on optimized menus for advanced life support. Life Support and Biosphere Science, 8(3/4), 199-210
190. Wehkamp, C.A., M. Stasiak, J. Lawson, N. Yorio, G. Stutte, J. Richards, R. Wheeler, and M. Dixon. 2012. Radish (Raphanus sativa L. cv. Cherry Bomb II) growth, net carbon exchange rated, and transpiration at decreased atmospheric pressure and / or oxygen. Gravitational and Space Biol., Vol. 26(1), 3-16
191. Wheeler, R.M. and T.W. Tibbitts. 1986. Growth and tuberization of potato (Solanum tuberosum L) under continuous light. Plant Physiol., 801-804
192. Wheeler, R.M., C.L. Mackowiak, J.C. Sager, W.M. Knott, and C.R. Hinkle. 1990. Potato growth and yield using nutrient film technique. American Potato Journal, 67, 177-187
193. Wheeler, R.M., T.W. Tibbitts, and A.H. Fitzpatrick. 1991. Carbon dioxide effects on potato growth under different photoperiods and irradiance. Crop Science, 31, 1209-1213
194. Wheeler, R.M., C.L. Mackowiak, L.M. Siegriest, and J.C. Sager. 1993a. Supraoptimal carbon dioxide effects on growth of soybean (Glycine max (L.) Merr.). J. Plant Physiol. 142:173-178.
195. Wheeler, R.M., K.A. Corey, J.C. Sager, and W.M. Knott. 1993b. Gas exchange rates of wheat stands grown in a sealed chamber. Crop Sci., 33, 161-168
196. Wheeler, R.M., G.W. Stutte, C.L. Mackowiak, N.C. Yorio, and L.M. Ruffe. 1995. Accumulation of possible potato tuber-inducing factor in continuous use recirculating NFT systems. HortSci., 30, 790 (#262)
197. Wheeler, R.M., C.L. Mackowiak, G.W. Stutte, J.C. Sager, N.C. Yorio. L.M. Ruffe, R.E. Fortson, T.W. Dreschel, W.M. Knott, and K.A. Corey. 1996a. NASA’s Biomass Production Chamber: A testbed for bioregenerative life support studies. Adv. Space Res., 18(4/5), 215-224
198. Wheeler, R.M., B.V. Peterson, J.C. Sager, and W.M. Knott. 1996b. Ethylene production by plants in a closed environment. Adv. Space Res., 18(4/5), 193-196
199. Wheeler, R.M. and C. Martin-Brennan (eds.). 2000. Mars greenhouses: Concept and Challenges. Proceedings from a 1999 Workshop. NASA Tech. Memorandum 208577
200. Wheeler, R.M., B.V. Peterson, and G.W. Stutte. 2004. Ethylene production throughout growth and development of plants. HortScience, 39(7), 1541-1545
201. Wheeler, R.M., G.W. Stutte, C.L. Mackowiak, N.C. Yorio, J.C. Sager, and W.M. Knott. 2008. Gas exchange rates of potato stands for bioregenerative life support. Adv. Space Res., 41, 798-806
202. Wolverton, B.C., R.C. McDonald, and W.R. Duffer. 1983. Microorganisms and plants for waste water treatment. J. Environ. Qual., 12, 236-242
203. Wolff, S.A., L.H. Coelho, M. Zabrodina, E. Brinckmann, A.-I. Kittang. 2013. Plant mineral nutrition, gas exchange and photosynthesis in space: A review. Adv. Space Res., 51, 465-475
204. Wright, B.D., W.C. Bausch, and W.M. Knott. 1988. A hydroponic system for microgravity plant experiments. Trans. Amer. Soc. Agricul. Eng., 31, 440-446
205. Yamashita, M, N. Katayama, H. Hashimoto, and K. Toita-Yokotani. 2007. Space agriculture for habitation on Mars – Perspective from Japan and Asia. J. Jpn. Soc. Microgravity Appl., 24(4), 340-347
206. Yamashita, M. H. Hashimoto, and H. Wada. 2009. On-site resources availability for space agriculture on Mars. In: V. Badescu (ed.), Mars: Prospective Energy and Material Resources, Springer-Verlag, Berlin. pp. 517-542
207. Zabel, P., M. Bamsey, D. Schubert, M. Tajmar. 2016. Review and analysis of over 40 years of space plant growth systems. Life Sciences in Space Research, 10, 1–16
References
1. Tolley-Henry, L. and C.D. Raper Jr. 1986. Utilization of ammonium as a nitrogen source. Effects of ambient acidity on growth and nitrogen accumulation by soybean. Plant Physiol., 82, 54-60
2. Tikhomirova N.A., S.A. Ushakova, N.P. Kovaleva, I.V. Gribovskaya, and A.A. Tikhomirov. 2005. Influence of high concentrations of mineral salts on production process and NaCl accumulation by Salicornia europaea plants as a constituent of the LSS phototroph link. Adv. Space Res., 35, 1589-1593
3. Tikhomirov A.A., S.A. Ushakova, N.S. Manukovsky, G.M. Lisovsky, Yu. A. Kudenko, Kovalev, I.V. Gribovskaya, L.S. Tirranen, I.G. Zolotukhin, J.B. Gros, Ch. Lasseur. 2003. Synthesis of biomass and utilization of plants wastes in a physical model of biological life-support system. Acta Astronautica, 53, 249-257
4. Tibbitts, T.W. and D.K. Alford. 1982. Controlled ecological life support system. Use of higher plants. NASA Conf. Publ., 2231
5. Tennessen, D.J., R.L. Singsaas, and T.D. Sharkey. 1994. Lightemitting diodes as a light source for photosynthesis research. Photosynthesis Research, 39, 85-92
6. Taub, R.B. 1974. Closed ecological systems. In: R.F. Johnston, P.W. Frank, and C.D. Michener (eds.) Annual Review of Ecology and Systematics. Annual Reviews Inc., Palo Alto, CA. pp. 139-160
7. Tang, Y. S. Guo, W. Dong, L. Qin, W. Ai, and S. Lin. 2010. Effects of long-term low atmospheric pressure on gas exchange and growth of lettuce. Adv. Space Res., 46, 751-760
8. Tani, A., Y. Kitaya, M. Kiyota, I. Aiga, and K. Nitta. 1996. Problems related to plant cultivation in a closed system. Life Support and Biosphere Sci., 3, 129-140
9. Tako, Y., R. Arai, S. Tsuga, O., Komatsubara, T. Masuda, S. Nozoe, and K. Nitta. 2010. CEEF: Closed Ecology Experiment Facilities. Gravitation and Space Biol., 23(2), 13-24
10. Tako, Y. S. Tsuga, T. Tani, R. Arai, O. Komatsubara, and M. Shinohara. 2008. On-week habitation of two humans in an airtight facility with two goats and 23 crops—Analysis of carbon, oxygen, and water circulation. Adv. Space Res., 41, 714-724
11. Tako, Y., R. Arai, K. Otsubo, and K. Nitta. 2001. Integration of sequential cultivation of main crops and gas and water processing subsystems using closed ecology experiment facility. SAE Technical Paper, 2001-01-2133
12. Sytchev, V.N., M.A. Levinskikh, S.A. Gostimsky, G.E. Bingham, and I.G. Podolsky. 2007. Spaceflight effects on consecutive generations of peas grown onboard the Russian segment of the International Space Station. Acta Astronautica, 60, 426-432
13. Sytchev, V.N., E.Ya. Shepelev, G.I. Meleshhko, T.S. Gurieva, M.A. Levinskikh, I.G. Podolshy, O.A. Dadsheva, and V.V. Popov. 2001. Main characteristics of biological components of developing life support system observed during experiment about orbital complex MIR. Adv. Space Res., 27(9), 1529-1534
14. Sugimoto, M. Y. Oono, O. Gusev, T. Matsumoto, T. Yazawa, M. A. Levinshkikh, V.N. Sychev, G.E. Bingham, R. Wheeler and M. Hummerick. 2014. Genome-wide expression analysis of reactive oxygen species gene network in mizuna plants grown in long-term spaceflight. BMC Plant Biology, 2014, 14, 4
15. Stutte, G.W., O. Monje, G.D. Goins, and B.C. Tripathy. 2005. Microgravity effects on thylakoid, leaf, and whole canopy photosynthesis of dwarf wheat. Planta, 223, 46-56
16. Subbarao, G.V., R.M. Wheeler, and G.W. Stutte. 2000. Feasibility of substituting sodium for potassium in crop plants for advanced life support systems. Life Sup. Biosphere Sci., 7, 225-232
17. Stutte, G.W., C.L. Mackowiak, N.C. Yorio, and R.M. Wheeler. 1999. Theoretical and practical considerations of staggered crop production in a BLSS. Life Support Biosphere Sci., 6, 287-291
18. Strayer, R.F., M.P. Alazraki, N. Yorio, and B.W. Finger. 1998. Bioprocessing wheat residues to recycle plant nutrients to the JSC variable pressure growth chamber during the L/MLSTP Phase III test. SAE Tech. Paper Series 981706
19. Stasiak, M., D. Gidzinski, M. Jordan, and M. Dixon. 2012. Crop selection for advanced life support systems in the ESA MELiSSA program: Durum wheat (Triticum turgidum var. durum). Adv. Space Res., 49, 1684-1690
20. Stasiak, M.A., R. Cote, M. Dixon, and B. Grodzinski. 1998. Increasing plant productivity in closed environments with inner canopy illumination. Life Supp. Biosph. Sci., 5, 175-182
21. Stasiak, M., G. Waters, Y. Zheng, B. Grodzinski and M. Dixon. 2003. Integrated multicropping of beet and lettuce and its effect on atmospheric stability. SAE Technical Paper, 2003-01-2357
22. Sorokin, C. and J. Myers. 1953. A high-temperature strain of Chlorella. Science, 117, 330-331
23. Schwartzkopf, S.H. and R.L. Mancinelli. 1991. Germination and growth of wheat in simulated Martian atmospheres. Acta Astronautica, 25(4), 245-247
24. Schwartzkopf, S.H. 1985. A non-destructive method for monitoring plant growth. HortSci., 20, 432-434
25. Schuerger, A.C., C.S. Brown, and E.C. Stryjewski. 1997. Anatomical features of pepper plants (Capsicum annuum L.) grown under red light-emitting diodes supplemented with blue or far-red light. Ann. Botany, 79, 273-282
26. Schubert, D. D. Quantius, J. Hauslage, L. Glasgow, F. Schröder, and M. Dorn. 2011. Advanced Greenhouse Modules for use within Planetary Habitats. 41st ICES, Portland, Oregon AIAA 2011-5166
27. Salisbury, F.B., W. F. Campbell, J. G. Carman, G. E. Bingham, D. L. Bubenheim, B. Yendler, V. Sytchev, M. A. Levinskikh, I. Ivanova, L. Chernova and I. Podolsky. 2003. Plant growth during the greenhouse II experiment on the Mir orbital station. Adv. Space Res., 31(1), 221-227
28. Salisbury, F.B., J.E. Gitelson, and G.M. Lisovsky. 1997. Bios-3: Siberian experiments in bioregenerative life support. BioScience, 47, 575-585
29. Salisbury, F.B. 1991. Lunar farming: Achieving maximum yield for the exploration of space. HortScience, 26(7), 827-833
30. Sadler, P.D. and G.A. Giacomelli. 2002. Mars inflatable greenhouse analog. Life Support Biosphere Sci., 8, 115-123
31. Sadler, P. 1995. The Antarctic horticultural project. Proc. Hydroponic Soc. Amer. 16th Ann. Conf. on Hydroponics, Tucson, AZ. pp. 95-107
32. Rygalov, V.Y., P. A. Fowler, R.M. Wheeler, and R.A. Bucklin. 2004. Water cycle and its management for plant habitats at reduced pressures. Habitation, 10(1), 49-59
33. Rossignoli, S. and Aero Sekur Inc. 2016. Co-organizer and sponsor of AgroSpace Workshops from 2006-2016: http://www.agrospaceconference.com/
34. Resh, H.M. 1989. Hydroponic food production. 4th Edition. Woodbridge Press Publ. Comp., Santa Barbara CA. pp. 462
35. Ren, J., S. Guo, C. Xu, C. Yang, W. Ai, Y. Tang, and L. Qin. 2014. Effects of different carbon dioxide and LED lighting levels on the anti-oxidative capabilities of Gynura bicolor DC. Adv. Space Res., 53, 353-361
36. Qin, L., S. Guo, W. Ai, Y. Tang, Q. Cheng, G. Chen. 2013. Effect of salt stress on growth and physiology in amaranth and lettuce: Implications for bioregenerative life support system. Adv. Space Res., 51, 476-482
37. Qin, L., S. Guo, W. Ai, and Y. Tang. 2008. Selection of candidate salad vegetables for controlled ecological life support system. Advances in Space Research, 41, 768-772
38. Prince, R.P. and W.M. Knott. 1989. CELSS Breadboard Project at the Kennedy Space Center. In D.W. Ming and D.L. Henninger (eds.). Lunar Base Agriculture: Soils for Plant Growth. Amer. Soc. Of Agronomy, Madison, WI, USA. pp. 155-163
39. Porter M.A. and B. Grodzinski. 1985. CO2 enrichment of protected crops. Horticultural Reviews, 7, 345-398
40. Prince, R.P. and J.W. Bartok. 1978. Plant spacing for controlled environment plant growth. Trans. Amer. Soc. Agric. Eng., 21, 332-336
41. Paul, A-L., A.C. Schuerger, M.P. Popp, J.T. Richards, M.S. Manak, R.J. and Ferl. 2004. Hypobaric biology: Arabidopsis gene expression at low atmospheric pressure. Plant Physiol., 134, 215-223
42. Patterson, R.L., G.A. Giacomelli, and P.A. Sadler. 2008. Resource and production model for the South Pole food growth chamber. SAE Technical Paper, 2008-01-2011
43. Paradiso, R., V. De Micco, R. Buonomo, G. Aronne, G. Barbier, and S. De Pascale. 2014. Soilless cultivation of soybean for Bioregenerative Life-Support Systems: a literature review and the experience of the MELiSSA Project – food characterization Phase I. Plant Biology, 16, (Suppl. 1), 69–78
44. Paradiso, R., R. Buonomo, V. De Micco, G. Aronne, M. Palermo, G. Barbieri, and S. De Pascale. 2012. Soybean cultivar selection for bioregenerative life support systems (BLSSs) – Hydroponic cultivation. Adv. Space Res., 50, 1501-1511
45. Ohler, T.A. and C.A. Mitchell. 1996. Identifying yield-optimizing environments for two cowpea-breeding lines by manipulating photoperiod and harvest scenario. J. Amer. Soc. Hort. Sci., 121, 576-581
46. Nitta, K. and M. Yamashita. 1985. Concept study on the technology of CELSS. Earth-Orient. Applic. Space Technol., 5(3), 253-263
47. Nitta, K. K. Otsubo, and A. Ashida. 2000. Integration test project of CEEF—A test bed for closed ecological life support Systems Adv. Space Res., 26, 335-338
48. Nelson, M., W.F. Dempster, J.P. Allen, S. Silverston, A. Alling, and M. van Thillo. 2008. Cowpeas and pinto beans: Performance and yield of candidate space crops in the laboratory biosphere closed ecological system. Adv. Space Res. 41, 748-753
49. Nelson, M., W.F. Dempster, S. Silverstone, A. Alling, J.P. Allen and M. van Thillo. 2005. Crop yield and light/energy efficiency in a closed ecological system: Laboratory biosphere experiments with wheat and sweet potato. Advances in Space Research, 35(9), 1539-1543
50. Myers, J. 1954. Basic remarks on the use of plants as biological gas exchangers in a closed system. J. Aviation Med., 25, 407-411
51. Nakamura, T., A.D. van Pelt, N.C. Yorio, A.E. Drysdale, R.M. Wheeler, and J.C. Sager. 2009. Transmission and distribution of photosynthetically active radiation (PAR) from solar and electric light sources. Habitation, 12(1), 103-117
52. Mortley, E.G., C.K. Bonsi, P.A. Loretan, W.A. Hill, and C.E. Morris. 2000. High relative humidity increases yield, harvest index, flowering, and gynophore growth of hydroponically grown peanut plants. HortSci., 35, 46-48
53. Mortley, D., J. Hill, P. Loretan, C. Bonsi, and W. Hill. 1996. Elevated carbon dioxide influences yield and photosynthetic responses of hydroponically-grown sweetpotato. Acta Hort., 440, 31-36
54. Mortley, D.G., C.K. Bonsi, W.A. Hill, P.A. Loretan, and C.E. Morris. 1993. Irradiance and nitrogen to potassium ratio influences sweetpotato yield in nutrient film technique. Crop Science, 33, 782-784
55. Mortley, D.G., C.K. Bonsi, P.A. Loretan, C.E. Morris, W.A. Hill, and C.R. Ogbuehi. 1991. Evaluation of sweet potato genotypes for adaptability to hydroponic systems. Crop Sci., 31, 845-847
56. Morrow, R.C. 2008. LED lighting in horticulture. HortScience, 43(7), 1947-1950
57. Morrow, R.C., W.R. Dinauer, R.J. Bula, and T.W. Tibbitts. 1993. The ASTROCULTURE™-1 flight experiment: Pressure control of the WCSAR porous tube nutrient delivery system. SAE Technical Paper Series, No. 932292
58. Monje, O., G. Stutte, and D. Chapman. 2005. Microgravity does not alter plant stand gas exchange of wheat at moderate light levels and saturating CO2 concentration. Planta, 222, 336-345
59. Monje, O., and B. Bugbee. 1998. Adaptation to high CO2 concentration in an optimal environment: Radiation capture, canopy quantum yield and carbon use efficiency. Plant Cell Environ., 21, 315-324
60. Miller, R.L. and C.H. Ward. 1966. Algal bioregenerative systems. In: E. Kammermeyer (ed.) Atmosphere in space cabins and closed environments. Appleton-Century-Croft Pub., New York, pp. 186-221
61. Mitchell, C.A., M.P. Dzakovich, C. Gomez, R. Lopez, J.F. Burr, R. Hernández, C. Kubota, C.J. Currey, Q. Meng, E. S. Runkle, C. M. Bourget, R.C. Morrow, and A.J. Both. 2015. Light-emitting diodes in horticulture. Horticultural Reviews, Volume 43, 1-87
62. Mergeay, M., W. Verstraete, G. Dubertet, M. Lefort-Tran, C. Chipaux, and R. Binot. 1987. MELISSA- A microorganisms-based model for CELSS develop. Proceedings 3rd European Symp. Space Thermal Control and Life Support Systems, Noordwijk, ESA SP-288. pp. 65-68
63. McAvoy, R.J., H.W. Janes, B.L. Godfriaux, M. Secks, D. Duchai, and W.K. Wittman. 1989. The effect of total available photosynthetic photon flux on single truss tomato growth and production. J. Hort. Science, 64, 331-338
64. Matthern, R.O. and R.B. Koch. 1964. Developing an unconventional food, algae, by continuous culture under high light intensity. Food Technol., 18, 58-65
65. Masuda, T., T. Ogasawara, E. Harashima, Y. Tako, and K. Nitta. 2005. Evaluation and implementation of an advanced life support (ALS) menu for Closed ecology Experiment Facilities (CEEF). Eco-Engineering, 17(1), 55-60
66. Massa, G.E., N.F. Dufour, J.A. Carver, M.E. Hummerick, R.M. Wheeler, R.C. Morrow, T.M. Smith. 2016. VEG-01: Veggie hardware validation testing on the International Space Station. Open Agricul. (in press)
67. Massa, G.D, H.H. Kim, R.M. Wheeler, and C.A. Mitchell 2008. Plant productivity in response to LED lighting. HortScience, 43(7), 1951-1956
68. Mansell, R.L. 1968. Effects of prolonged reduced pressure on the growth and nitrogen content of turnip (Brassica rapa L.). SAM-TR-68-100. School of Aerospace Medicine, Brooks Air Force Base, Texas
69. Mackowiak, C.L, R.M. Wheeler, G.W. Stutte, N.C. Yorio, and L.M. Ruffe. 1998. A recirculating hydroponic system for studying peanut (Arachis hypogaea L.). HortScience, 33, 650-651
70. MacElroy, R.D. and J. Bredt. 1985. Current concepts and future directions of CELSS. Adv. Space Res., 4(12), 221-230
71. MacElroy, R.D., M. Kliss, and C. Straight. 1992. Life support systems for Mars transit. Adv. Space Res., 12(5), 159-166
72. Lobascio, C., M. Lamantea, S. Palumberi, V. Cotronei, B. Negri, S. De Pascale, A. Maggio, M. Maffei, and M. Fote. 2008. Functional architecture and development of the CAB bioregenerative system. SAE Technical Paper, 2008-01-2012
73. Lobascio, C., M. Lamantea, M.A. Perino, L. Bertaggia, V. Bornicsacci, and F. Piccolo. 2006. Plant facilities for inflatable habitats. ICES Tech. Paper, 2006-01-2214
74. Lisovsky, G.M., J.I. Gitelson, M.P. Shilenko, I.V. Brivovskaya, and I.M Trubachev. 1997. Direct utilization of human liquid wastes by plants in a closed ecosystem. Adv. Space Res., 20(10), 1801-1804
75. Loader, C.A., J.L. Garland, L.H. Levine, K.L. Cook, C.L. Mackowiak, and H.R. Vivenzio. 1999. Direct recycling of human hygiene water into hydroponic plant growth systems. Life Support Biosphere Sci., 6, 141-152
76. Levine, L.H., P.A. Bisbee, T.A. Richards, M.N. Birmele, R.L. Prior, M. Perchonok, M. Dixon, N.C. Yorio, G.W. Stutte, and R.M. Wheeler. 2008. Quality characteristics of radish grown under reduced atmospheric pressure. Adv. Space Res., 41, 754-762
77. Levinskikh, M.A., V.N. Sychev, T.A. Derendyaeva, O.B. Signalova, F.B. Salisbury, W.F. Campbell, G.E. Bingham, D.L. Bubenheim, and G. Jahns. 2000. Analysis of the spaceflight effects on growth and development of Super Dwarf wheat grown on the space station Mir. J. Plant Physiol., 156, 522-529
78. Ley, W. 1948. Rockets and space travel. The future of flight beyond the stratosphere. The Viking Press, New York, NY, USA. pp. 374
79. Lenk, S., L. Chaerle, E.E. Pfündel, G. Langsdorf, D. Hagenbeek, H.K. Lichtenthaler, D. Van Der Straeten, and C. Buschmann. 2007. Multispectral fluorescence and reflectance imaging at the leaf level and its possible applications. J. Experimental Botany, 58, 807-814
80. Law, J., M, Van Baalen, M. Foy, S.S. Mason, C. Mendez, M.L. Wear, V.E. Meyers, and D. Alexander. 2014. Relationship between carbon dioxide levels and reported headaches on the International Space Station. J. Occupational Environ. Medicine, 56(5), 477-483
81. Lange, K, A.T. Perka, B.E. Duffield and F.F. Jeng 2005. Bounding the spacecraft atmosphere design space for future exploration missions. NASA Contractor Report CR-2005-213689
82. Lasseur, C., W. Verstraete, J.B. Gros, G. Dubertret, and F. Rogalla. 1996. MELISSA: a potential experiment for a precursor mission to the Moon. Adv. Space Res., 18, 111-117
83. Krall, A.R. and B. Kok. 1960. Studies on algal gas exchanges with reference to space flight. Developments in Industrial Microbiology, 1, 33-44
84. Krauss, R. 1962. Mass culture of algae for food and other organic compounds. Amer. J. Botany, 49, 425-435
85. Knight, S.L. and C.A. Mitchell. 1988. Effects of incandescent radiation on photosynthesis, growth rate and yield of Waldmann’s Green’ leaf lettuce . Scientia Horticulturae, 35, 37-49
86. Kliss, M., A.G. Heyenga, A. Hoehn and L.S. Stodieck. 2000. Recent advances in technologies required for a “Salad Machine”. Adv. Space Res., 26(2), 263-269
87. Kliss, M. and R.D. MacElroy. 1990. Salad machine: A vegetable production unit for long duration space missions. SAE Tech. Paper 901280. Williamsburg, VA, USA. July 1990
88. Klassen, S.P. and B. Bubgee. 2004. Ethylene synthesis and sensitivity in crop plants. HortScience, 39, 1546-1552
89. Kitaya, Y. H. Hirai, X. Wei, A.F.M.S. Islam, and M. Yamamoto. 2008. Growth of sweetpotato cultured in the newly designed hydroponic system for space farming. Adv. Space Res., 41, 730-735
90. Kitaya, Y. and H. Hirai. 2008. Effects of lighting and air movement on temperatures in reproductive organs of plants in a closed plant growth facility. Adv. Space Res., 41, 763-676
91. Kitaya, Y. M. Kawai, J. Tsuruyama, H. Takahashi, A. Tani, E. Goto, T. Saito, M. Kiyota. 2003. The effect of gravity on surface temperature of plant leaves. Plant, Cell Environment, 26, 497-503
92. Kim, H-H., J. Norikane, R.M. Wheeler, J.C. Sager, and N.C. Yorio. 2007. Electric lighting considerations for crop production in space. Acta Horticulturae, 761, 193-202
93. Kim, H-H., G.D. Goins, R.M. Wheeler, and J.C. Sager. 2004. Stomatal of lettuce grown under or exposed to different light qualities. Annals of Botany, 94, 691-697
94. Kibe, S. and K. Suzuki. 1997. Japan’s activities on CELSS in space. In: P. M. Bainum, G.L. May, M. Nagatomo, K.T. Uesugi, F. Bingchen, and Z. Hui (eds.), Space Cooperation into the 21st Century (7th ISCOPS) AAS 97-459, 96, 605-125
95. Katayama, N., Y. Ishikawa, M. Takaoki, M. Yamashita, S. Nakayama, K. Kiguchi, R. Kok, H. Wada, J. Mitsuhashi,. 2008. Entomophagy: A key to space agriculture. Adv. Space Res., 41, 701-705
96. Karel, M., A.R. Kamarel, and Z. Nakhost. 1985. Utilization of non-conventional systems for conversion of biomass to food components. Potential for utilization of algae in engineered foods. NASA CR-176257
97. Kacira, M., G. Giacomelli, L. Patterson, R. Furfaro, P. Sadler, G. Boscheri, C. Lobascio, M. Lamantea, R. Wheeler, and S. Rossignoli. 2012. System dynamics and performance factors of a lunar greenhouse prototype bioregenerative life support system. Acta Hort., 952, 575-582
98. Jasoni, R., C. Kane, C. Green, E. Peffley, D. Tissue, L. Thompson, P. Payton, and P. W. Paré. 2004. Altered leaf and root emissions from onion (Allium cepa L.) grown under elevated CO2 conditions. Environment and Experimental Botany., 51, 273-280
99. Iwabuchi, K. and K. Kurata. 2003. Short-term and long-term effects of low total pressure on gas exchange rates of spinach. Adv. Space Res., 31(1), 241-244
100. Iwabuchi, K., E. Goto, and T. Takakura. 1996. Germination and growth of spinach under hypobaric conditions. Environ. Control in Biol., 34, 169-178
101. Hummerick, M.E., J. Garland, G. Bingham, V.N. Sychev, and I.G. Podolsky. 2010. Microbiological analysis of Lada Vegetable Production Units (VPU) to define critical control points and procedures to ensure the safety of space grown vegetables. Amer. Inst. Aeronautics Astronautics, 40th ICES meeting, Barcelona, Spain, July 11-15, 2010. AIAA-2010-6253
102. Hoff, J.E., J.M. Howe, and C.A. Mitchell. 1982. Nutritional and cultural aspects of plant species selection for a regenerative life Support system. Report to NASA Ames Research Center, NSG2401 and NSG 2404
103. Heinse, R., S.B. Jones, M. Tuller, G.E. Bingham, I. Podolskiy, and D. Or. 2009. Providing optimal root-zone fluid fluxes: Effects of hysteresis on capillary-dominated water distributions in reduced gravity. SAE Technical Paper, 2009-01-2360
104. Heinse, R., S.B. Jones, S.L. Steinberg, M. Tuller, and D. Or. 2007. Measurements and modeling of variable gravity effects on water distribution and flow in unsaturated porous media. Vadose Zone J., 6, 713–724
105. He, C., R.T. Davies, and R.E. Lacey. 2009. Ethylene reduces gas exchange and growth of lettuce plants under hypobaric and normal atmospheric conditions. Physiol. Plant,135, 258-271
106. He, C., F.R. Davies, and R.E. Lacey. 2007. Separating the effects of hypobaria and hypoxia on lettuce: growth and gas exchange. Physiologia Plantarum, 131, 226-240
107. Guo, S., X. Liu, W. Ai, Y. Tang, J. Zhu,, X. Wang, M. Wei, L. Qin, and Y. Yang. 2008. Development of an improved ground-based prototyped of space plant-growing facility. Adv. Space Res., 41, 736-741
108. Guerra, D., A.J. Anderson, and F.B. Salisbury. 1985. Reduced phenylalanine ammonia-lyase and tyrosine ammonia-lyase activities and lignin synthesis in wheat grown under low-pressure sodium lamps. Plant Physiol., 78, 126-130
109. Guerra, D., A.J. Anderson, and F.B. Salisbury. 1985. Reduced phenylalanine ammonia-lyase and tyrosine ammonia-lyase activities and lignin synthesis in wheat grown under low-pressure sodium lamps. Plant Physiol., 78, 126-130
110. Grotenhuis, T.P. and B. Bugbee. 1997. Super-optimal CO2 reduces seed yield but not vegetative growth in wheat. Crop Science, 37, 1215-1222
111. Gros, J.B., L. Poughon, C. Lasseur, and A. A. Tikhomirov. 2004. Recycling efficiencies of C, H, O, N, S, and P elements in a biological life support system based on microorganisms and higher plants Advances in Space Research, 31, 195-199
112. Greg, P. 2006. Across the zodiac. BiblioBazaar ISBN-1-4264-4026-X (originally written in 1880)
113. Grodzinski, B. 1992. Plant nutrition and growth regulation by CO2 enrichment. BioScience, 42, 517-525
114. Goto, E. 2012. Plant production in a closed plant factory with artificial lighting. Acta Hort., 956, 37-50
115. Goto, E., Ohta, H., Iwabuchi, K., Takakura, T. 1996. Measurement of net photosynthetic and transpiration rates of spinach and maize plants under hypobaric conditions. J. Agric. Meteorol., 52, 117–123
116. Golueke, C.G. and W.J. Oswald. 1964. Role of plants in closed systems. Ann. Rev. Plant Physiol., 15, 387-408
117. Goldman, K.R. and C.A. Mitchell. 1999. Transfer from long to short photoperiods affects production efficiency of day-neutral rice. HortScience, 34, 875-877
118. Goins, G.D., L.M. Ruffe, N.A. Cranston, N.C. Yorio, R.M. Wheeler, and J.C. Sager. 2001. Salad crop production under different wavelengths of red light-emitting diodes (LEDs). Soc. Automotive Eng. Tech. Paper, 2001-01-2422
119. Goins, G.D., N.C. Yorio, M.M. Sanwo, and C.S. Brown. 1997. Photomorphogenesis, photosynthesis, and seed yield of wheat plants grown under red light-emitting diodes (LEDs) with and without supplemental blue lighting. J. Exp. Bot., 48, 1407-1413
120. Godia, F., J. Albiol, J. Perez, N. Creus, F. Cabello, A. Montras, A. Maso, and Ch. Lasseur. 2004. The MELISSA pilot plant facility as an integration test-bed for advanced life support systems. Advances in Space Research, 34, 1483-1493
121. Gitelson, J.I. and Yu. N. Okladnikov. 1994. Man as a component of a closed ecological life support systems. Life Support Biosphere Sci., 1, 73-81
122. Gitelson, J.I., I.A. Terskov, B.G. Kovrov, G.M. Lisoviskii, Yu. N. Okladnikov, F. Ya. Sid’ko, I.N. Tuubachev, M.P. Shilenko, S.S. Alekseev, I.M. Pan’kova, and L.S. Tirranen. 1989. Long-term experiments on man’s stay in biological life-support system. Adv. Space Res., 9(8), 65-71
123. Gitelson, J.I., I.A. Terskov, B.G. Kovrov, R. Ya. Sidko, G.M. Lisovsky, Yu. N. Okladnikov, V.N. Belyanin, I.N. Trubachov, and M.S. Rerberg. 1976. Life support system with autonomous control employing plant photosynthesis. Acta Astronautica, 3, 633-650
124. Gitelson, I.I., B.G. Kovrov, G.M. Lisovsky, Y.N. Okladikova, M.S. Rerberg, F.Y. Sidko, and I. A. Terskov. 1975. Toxic gases emitted by Chlorella. In: Problems in Space Biology
125. Gianfagna, T.J., L. Logendra, E.F. Durner, and H.W. Janes. 1998. Improving tomato harvest index by controlling crop height and side shoot production. Life Support and Biosphere Science, 5, 255-262
126. Gerbaud, A. M. Andre, and C. Richaud. 1988. Gas exchange and nutrition patterns during the life cycle of an artificial wheat crop. Physiol. Plant., 73, 471-478
127. Gazenko, O.G. 1967. Development of biology in the USSR. In: Soviet Science and Technology for 50 years. Nauka Press, Moscow (In Russian; citation from Salisbury et al., 1997).
128. Fu, Y. L. Li, B. Xie, C. Dong, M. Wang, B. Jia, L. Sho, Y. Dong, S. Deng, H. Liu, G. Liu, B. Liu, D. Hu, and H. Liu. 2016. How to establish a bioregenerative life support system for long-term crewed missions to the Moon and Mars. Astrobiology (In Press)
129. Frantz, J.M., R.J. Joly, and C.A. Mitchell. 2000. Intracanopy lighting influences radiation capture, productivity, and leaf senescence in cowpea canopies. J. Amer. Soc. Hort. Sci., 125, 694-701
130. Fowler, P.A., R.M. Wheeler, R.A. Bucklin, and K.A. Corey. 2000. Low pressure greenhouse concepts for Mars. In: R.M. Wheeler and C. Martin-Brennan (eds.) Mars greenhouses: Concept and Challenges. NASA Tech. Mem. 208577
131. Fong, F. and E.A. Funkhouser. 1982. Air pollutant production by algal cell cultures. NASA Cooperative Agreement NCC 2-102
132. Eley, J.H. and J. Myers. 1964. Study of a photosynthetic gas exchanger. A quantitative repetition of the Priestley experiment. Tex. J. Sci., 16, 296-333
133. Edeen, M.A., J.S. Dominick, D.J. Barta and N.J.C Packham. 1996. Control of air revitalization using plants: Results of the early human testing initiative Phase I Test. SAE Tech. Paper Series, No. 961522
134. Dreschel, T.W. and J.C. Sager. 1989. Control of water and nutrient using a porous tube: A method for growth plants in space. HortScience, 24, 944-947
135. Dougher, T.A.O. and B.G. Bugbee. 2001. Differences in the response of wheat, soybean and lettuce to reduced blue radiation. Photochem. Photobiol., 73, 199-207
136. Dong, C., Y. Fu, G. Liu, and H. Liu. 2014b. Low light intensity effects on the growth, photosynthetic characteristic, antioxidant capacity, yield and quality of wheat (Triticum aestivum L.) at different growth states in BLSS. Adv. Space Res., 53, 1557-1566
137. Dixon, M., D. Schmitt. 2001. A Canadian Vision for Advanced Life Support. The Canadian Journal of Space Exploration., 1,1, 6-12
138. Dong, C., Y. Fu, G. Liu, and H. Liu. 2014a. Growth photosynthetic characteristics, antioxidant capacity and biomass yield and quality of wheat (Triticum aestivum L.) exposed to LED light sources with different spectra combinations. J. Agronomy and Crop Sci., 200, 219-230
139. De Micco, V. R. Buonomo, R. Paradiso, S. De Pascale, and G. Aronne. 2012. Soybean cultivar selection for Bioregenerative Life Support Systems (BLSS) – Theoretical selection. Adv. Space Res., 49, 1415-1421
140. Davis, N. 1985. Controlled-environment agriculture – Past, present, and future. Food Technology, 39, 124-126
141. Daunicht, H.-J. and H.-J. Brinkjans. 1992. Gas exchange and growth of plants under reduced air pressure. Advances in Space Research, 12(5), 107-114
142. Croxdale, J., M. Cook, T.W. Tibbitts, C.S. Brown, and R.M. Wheeler. 1997. Structure of potato tubers formed during spaceflight. J. Exp. Bot., 48, 2037-2043
143. Corey, K.A., D.J. Barta, and R.M. Wheeler. 2002. Toward Martian agriculture: Responses of plants to hypobaria. 2002. Life Sup. Biosphere Sci., 8,103-114
144. Cuello, J.D., D. Jack, E. Ono, and T. Nakamura. 2000. Supplemental terrestrial solar lighting for an experimental subterranean biomass production chamber. Soc. Automotive Eng. Tech. Paper, 2000-01-2428
145. Corey, K.A., D.J. Barta, and D.L. Henninger. 1997. Photosynthesis and respiration of a wheat stand at reduced atmospheric pressure and reduced oxygen. Adv. Space Res., 20(10), 1869-1877
146. Cook, M.E., J.L. Croxdale, T.W. Tibbitts, C.S. Brown, and R.M. Wheeler. 1998. Development and growth of potato tubers in microgravity. Advances in Space Research, 21,1103-1110
147. Chamberlain, C.P., M.A. Stasiak and M.A. Dixon. 2003. Response of plant water status to reduced atmospheric pressure. SAE Technical Paper Series, 2003-01-2677
148. Chaerle, L., D. Hagenbeek, X. Vanrobaeys, and D. Van Der Straeten. 2007. Early detection of nutrient and biotic stress in Phaseolus vulgaris. Intl. J. Remote Sensing, 28, 3479-3492
149. Cao, W. and T.W. Tibbitts. 1991. Potassium concentrations effect on growth, gas exchange, and mineral accumulation in potatoes. J. Plant Nutr., 14, 525-537
150. Cao, W. and T.W. Tibbitts. 1994. Phasic temperature change patterns affect growth and tuberization in potatoes. J. Amer. Soc. Hort. Sci., 119, 775-778
151. Cathey, H.M. and L.E. Campbell. 1980. Light and lighting systems for horticultural plants. Horticultural Reviews, 2, 491-537
152. Burg, S.P. and E.A. Burg. 1966. Fruit storage at subatmospheric pressures. Science, 153, 314-315
153. Bula, R.J., R.C. Morrow, T.W. Tibbitts, D.J. Barta, R.W. Ignatius, and T.S. Martin. 1991. Light-emitting diodes as a radiation source for plants. HortScience, 26, 203-205
154. Bucklin, R.A., P.A. Fowler, V.Y Rygalov, R.M. Wheeler, Y. Mu, L. Hublitz, and E.G. Wilkerson. 2004. Greenhouse design for the Mars environment: Development of a prototype deployable dome. Acta Horticulturae, 659, 127-134
155. Bugbee, B.G 1995. Nutrient management in recirculating hydroponic culture. 1995 Proceedings from the Hydroponic Society of America, pp 15-30
156. Bugbee, B. and O. Monje. 1992. The limits of crop productivity. BioScience, 42, 494-502
157. Bugbee, B., B. Spanarkel, S. Johnson, O. Monje, and G. Koerner. 1994. CO2 crop growth enhancement and toxicity in wheat and rice. Adv. Space Res., 14, 257-267
158. Bubgee, B.G. and F.B. Salisbury. 1988. Exploring the limits of crop productivity. Photosynthetic efficiency of wheat in high irradiance environments. Plant Physiol., 88, 869-878
159. Bonsi, C.K., P.A. Loretan, W.A. Hill, and D.G. Mortley. 1992. Response of sweetpotatoes to continuous light. HortSci., 27, 471
160. Brown, C.S., T.W. Tibbitts, J.G. Croxdale, and R.M. Wheeler. 1997. Potato tuber formation in the spaceflight environment. J. Life Support and Biosphere Sci., 4, 71-76
161. Boeing Comp. 1962. Investigations of selected higher plants as gas exchange mechanism for closed ecological systems. In: Biologistics for Space Systems Symposium, May 1962. AMRL-TDR-62-116, Wright-Patterson Air Force Base, Ohio, USA
162. Bonsi, C.K., D.G. Mortley, P.A. Loretan, and W.A. Hill. 1994. Temperature and light effects of sweetpotatoes grown hydroponically. Acta Hort., 361, 527-529
163. Bingham, G.E., T.S. Topham, A. Taylor, I.G. Podolshy, M.A. Levinskikh, and V.N. Sychev. 2003. Lada: ISS plant growth technology checkout. SAE Technical Paper, 2003-01-2613
164. Bingham, G.E., Levinskikh, M.A., Sytchev V.N., and I.G. Podolsky. 2000. Effects of gravity on plant growth. J. Grav. Physiol., 7, 5-8
165. Bingham, G., F. Salisbury, W. Campbell, J. Carman, B.Y. Yendler, V. S. Sytchev, Y. B. Berkovich, M. A. Levinskikh and I. Podolsky. 1996. The spacelab-Mir-1 “Greenhouse-2” experiment. Adv. Space Res., 18, 225-232
166. Berkovich, Yu. A., S.O. Smolyanina, N.M. Krivobok, A.N. Erokhin, A.N. Agureev, and N.A. Shanturin. 2009. Vegetable production facility as a part of a closed life support system in a Russian Martian space flight scenario. Adv. Space Res., 44, 170–176
167. Berkovich, Yu.A., N.M. Krivobok, Yu.Ye. Sinyak, S.O. Smolyanina, Yu.I. Grigoriev, S.Yu. Romanov and A.S. Guissenberg. 2004. Developing a vitamin greenhouse for the life support system of the International Space Station and for future interplanetary missions. Advances in Space Research, 34(7), 1552-1557
168. Berkovich, Yu. A., N M. Krivobok, and Yu. E. Sinyak. 1998. Project of conveyer-type space greenhouse for cosmonauts’ supply with vitamin greenery. Adv. Space Res., 22(10), 1401-1405
169. Barta, D.J., J.M. Castillo, and R.E. Fortson. 1999. The biomass production system for the bioregenerative planetary life support systems test complex: Preliminary designs and considerations. SAE Technical, Paper 1999-01-2188
170. Batten, J.H., G.W. Stutte, and R.M. Wheeler 1995. Effect of crop development on biogenic emissions from plant populations grown in a closed plant growth chambers. Phytochem., 39, 1351-1357
171. Barta, D.J., J.M. Castillo, and R.E. Fortson. 1999. The biomass production system for the bioregenerative planetary life support systems test complex: Preliminary designs and considerations. SAE Technical Paper, 1999-01-2188
172. Barta, D.J. and K. Henderson. 1998. Performance of wheat for air revitalization and food production during the Lunar-Mars life support test project phase III test. SAE Technical Paper, Series 98104
173. Barta, D.J., T.W. Tibbitts, R.J. Bula, and R.C. Morrow. 1992. Evaluation of light emitting diodes characteristics for a space-based plant irradiation source. Adv. Space Res., 12(5), 141-149
174. Barnes, C. and B. Bugbee. 1992. Morphological responses of wheat to blue light. J. Plant Physiol., 139,339-342
175. Barta, D.J. and T.W. Tibbitts. 1991. Calcium localization in lettuce leaves with and without tipburn: Comparison of controlled environment and field grown plants. J. Amer. Soc. Hort. Sci., 116, 870-875
176. Bamsey, M., Graham, T., Thompson, C., Bertinstain, A., Scott, A., M. Dixon, University of Guelph, Canada. 2012. Ion-Specific nutrient management in closed systems: the necessity for ion-selective sensors in terrestrial and space-based agriculture and water management systems. Sensors, 12(10), 13349-13391
177. Bamsey, M. T. Graham, M. Stasiak, A. Berinstain, A. Scott, and T. Rondeau Vuk, and M. Dixon. 2009. Canadian advanced life support capacities and future directions. Advances in Space Research, 44, 151-161
178. Averner, M., M. Karel, and R. Radmer. 1984. Problems associated with using algae in bioregenerative life support systems. NASA Contractor Report 166615, Ames Research Center, Moffett Field, CA
179. Ashida, A and K. Nitta. 1995. Construction of CEEF (Closed Ecology experiment Facility) is just started. SAE Tech., Paper 951584
180. Avercheva, O., Yu,A. Berkovich, S. Smolyanina, E. Bassarskaya, S. Pogosyan, V. Ptushenko, A. Erokhin, T. Zhigalova. 2014. Biochemical, photosynthetic and productive parameters of Chinese cabbage grown under blue–red LED assembly designed for space agriculture. Adv. Space Res., 53, 1574-1581
181. Andre, M. and D. Massimino. 1992. Growth of plants at reduced pressures: Experiments in wheat—technological advantages and constraints. Adv. Space Res., 12(5), 97-106
182. Andre, M., F. Cote, A. Gerbaud, D. Massimino, J. Massimino, and C. Richaud. 1989. Effect of CO2 and O2 on development and fructification of wheat in closed systems. Adv. Space Res., 9(8),17-28
183. Alling, A., M. Van Thillo, W. Dempster, M. Nelson, S. Silverstone, and J. Allen. 2005. Lessons learned from Biosphere 2 and laboratory biosphere closed systems experiment for the Mars on Earth project. Biological Sci. in Space, 19(4), 250-260
184. Tripathy, B.C. and C.S. Brown. 1995. Root-shoot interaction in the greening of wheat seedlings grown under red light. Plant Physiol., 107, 407-411
185. Tsiolkovsky, K.E. 1975. Study of outer space by reaction devices. In: NASA Technical Translation NASA TT F-15571 of “Issledovaniye mirovykh prostranstv reaktivnymi priborami”, Mashinotroyeniye Press, Moscow, 1967
186. Wada, H., M. Yamashita, N. Katayama, J. Mitsuhashi, H. Takeda, and H. Hashimoto. 2009. Agriculture on Earth and on Mars. In: J .H. Denis and P.D. Aldridge (eds.), Space Exploration Research, pp. 481-498
187. Wang, M., B. Xie, Y. Fu, C. Dong, L. Hui, L. Guanghui, and H. Liu. 2015a. Effects of different elevated CO2 concentrations on chlorophyll contents, gas exchange, water use efficiency, and PSII activity on C3 and C4 cereal crops in a closed artificial ecosystem. Photosynthesis Research, 126(2-3), 351-362
188. Wang, M., Y. Fu, and H. Liu. 2015b. Nutritional status and ion uptake response of Gynura bicolor DC between Porous-tube and traditional hydroponic growth systems. Acta Astronautica, 113, 13–21
189. Waters, G.R., A. Olabi, J.B. Hunter, M.A. Dixon and C. Lasseur. 2002. Bioregenerative food system cost based on optimized menus for advanced life support. Life Support and Biosphere Science, 8(3/4), 199-210
190. Wehkamp, C.A., M. Stasiak, J. Lawson, N. Yorio, G. Stutte, J. Richards, R. Wheeler, and M. Dixon. 2012. Radish (Raphanus sativa L. cv. Cherry Bomb II) growth, net carbon exchange rated, and transpiration at decreased atmospheric pressure and / or oxygen. Gravitational and Space Biol., Vol. 26(1), 3-16
191. Wheeler, R.M. and T.W. Tibbitts. 1986. Growth and tuberization of potato (Solanum tuberosum L) under continuous light. Plant Physiol., 801-804
192. Wheeler, R.M., C.L. Mackowiak, J.C. Sager, W.M. Knott, and C.R. Hinkle. 1990. Potato growth and yield using nutrient film technique. American Potato Journal, 67, 177-187
193. Wheeler, R.M., T.W. Tibbitts, and A.H. Fitzpatrick. 1991. Carbon dioxide effects on potato growth under different photoperiods and irradiance. Crop Science, 31, 1209-1213
194. Wheeler, R.M., C.L. Mackowiak, L.M. Siegriest, and J.C. Sager. 1993a. Supraoptimal carbon dioxide effects on growth of soybean (Glycine max (L.) Merr.). J. Plant Physiol. 142:173-178.
195. Wheeler, R.M., K.A. Corey, J.C. Sager, and W.M. Knott. 1993b. Gas exchange rates of wheat stands grown in a sealed chamber. Crop Sci., 33, 161-168
196. Wheeler, R.M., G.W. Stutte, C.L. Mackowiak, N.C. Yorio, and L.M. Ruffe. 1995. Accumulation of possible potato tuber-inducing factor in continuous use recirculating NFT systems. HortSci., 30, 790 (#262)
197. Wheeler, R.M., C.L. Mackowiak, G.W. Stutte, J.C. Sager, N.C. Yorio. L.M. Ruffe, R.E. Fortson, T.W. Dreschel, W.M. Knott, and K.A. Corey. 1996a. NASA’s Biomass Production Chamber: A testbed for bioregenerative life support studies. Adv. Space Res., 18(4/5), 215-224
198. Wheeler, R.M., B.V. Peterson, J.C. Sager, and W.M. Knott. 1996b. Ethylene production by plants in a closed environment. Adv. Space Res., 18(4/5), 193-196
199. Wheeler, R.M. and C. Martin-Brennan (eds.). 2000. Mars greenhouses: Concept and Challenges. Proceedings from a 1999 Workshop. NASA Tech. Memorandum 208577
200. Wheeler, R.M., B.V. Peterson, and G.W. Stutte. 2004. Ethylene production throughout growth and development of plants. HortScience, 39(7), 1541-1545
201. Wheeler, R.M., G.W. Stutte, C.L. Mackowiak, N.C. Yorio, J.C. Sager, and W.M. Knott. 2008. Gas exchange rates of potato stands for bioregenerative life support. Adv. Space Res., 41, 798-806
202. Wolverton, B.C., R.C. McDonald, and W.R. Duffer. 1983. Microorganisms and plants for waste water treatment. J. Environ. Qual., 12, 236-242
203. Wolff, S.A., L.H. Coelho, M. Zabrodina, E. Brinckmann, A.-I. Kittang. 2013. Plant mineral nutrition, gas exchange and photosynthesis in space: A review. Adv. Space Res., 51, 465-475
204. Wright, B.D., W.C. Bausch, and W.M. Knott. 1988. A hydroponic system for microgravity plant experiments. Trans. Amer. Soc. Agricul. Eng., 31, 440-446
205. Yamashita, M, N. Katayama, H. Hashimoto, and K. Toita-Yokotani. 2007. Space agriculture for habitation on Mars – Perspective from Japan and Asia. J. Jpn. Soc. Microgravity Appl., 24(4), 340-347
206. Yamashita, M. H. Hashimoto, and H. Wada. 2009. On-site resources availability for space agriculture on Mars. In: V. Badescu (ed.), Mars: Prospective Energy and Material Resources, Springer-Verlag, Berlin. pp. 517-542
207. Zabel, P., M. Bamsey, D. Schubert, M. Tajmar. 2016. Review and analysis of over 40 years of space plant growth systems. Life Sciences in Space Research, 10, 1–16