• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
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    • 专利摘要:
    The present invention relates to the biological production of methane (biogas) by co-cultivation in an aerobic atmosphere of a methanogenic bacterium and an anaerobic bacterium capable of producing hydrogen, in a culture medium comprising or being supplemented with a compound ( s) hydrocarbon (s), including starch and / or sugars, and supplemented with antioxidant compound (s).
    公开号:FR3020380A1
    申请号:FR1455745
    申请日:2014-06-20
    公开日:2015-10-30
    发明作者:Didier Raoult;Saber Khelaifia;Michel Drancourt
    申请人:Aix Marseille Universite;Fondation Mediterranee Infection;
    IPC主号:
    专利说明:

    [0001] PROCESS FOR PRODUCTION OF METHANE BY AEROBIC CO-CULTURE OF ANAEROBIC MICROORGANISMS The present invention relates to a process for the production of methane gas (CH4) by aerobically microbial culture of anaerobic microorganisms. Biologically produced methane has been considered until recently, as being produced only anaerobically, that is to say without oxygen, and usually in the presence of hydrogen, by anaerobic fermentation of a number of organic waste.
    [0002] In FR2537992, CH4 gas is produced by fermentation and anaerobic degradation of organic waste. To do this, hydrogen is injected which reacts with the CO2 produced to form CH4 and thus reduce the CO2 content mixed with CH4. 10 to 5000 liters of H2 gas are required per m3 of CH4 produced.
    [0003] In FR2601690, a thermophilic Methanococcus therrnolitotrophicus methanogen is used under H 2 / CO 2 feed, the culture being carried out in a medium essentially containing a source of nitrogen and a source of salts comparable to 110 ° C. under anaerobic conditions. Recent work, since 2006 (1), has shown that in the sea it has been possible to detect methane in an aerobic environment, exclusively after enrichment with methylphosphonate, by one or more nitrogen-fixing microorganisms (Karl DM, Beversdorf L , Bjorkman KM, Church MJ, Martinez A, DeLong EF, Aerobic production of methane in the sea Nat Geosci 2008; 1: 473-8).
    [0004] In addition, natural methane is produced in the intestine under anaerobic conditions under the activity of methanogenic microorganisms. In the digestive tract methane is produced under the action of methanogenic microorganisms Archae, in particular Methanobrevibacter srnithll or Methanornassilicoccus lurninyensis, which produce methane from hydrogen (H2) molecules produced by the fermentation of sugars by anaerobic bacteria of the digestive tract, in particular by Bacteroides, in particular by Bacteroides thetaiotaornicron.
    [0005] The object of the present invention is to provide a novel biotechnological process for producing methane under aerobic conditions. The inventors have surprisingly discovered that it is possible to allow the culture of anaerobic bacteria by combining with the culture medium, an antioxidant compound while maintaining the archaea culture methanogen. More specifically, the inventors have observed that the addition of antioxidant compounds in a culture medium in an aerobic atmosphere with an anaerobic bacterium capable of producing hydrogen, also allowed the cultivation of a methanogenic archaea, due to the production of hydrogen by said anaerobic bacterium. They were able to measure the production of hydrogen in the presence of said anaerobic bacterium and methane production by said archaea, done aerobically, by the combination of the two anaerobic microorganisms, including Methanobrevibacter srnithll or Methanornassiliicoccus lurninyensis and Bacteroides thetaiotaornicron. Thus, the production of single or double chambers of confection with one part Bacteroides thetaiotaornicron, or another anaerobic bacterium, and second Methanobrevibacter srnithll or Methanornassiliicoccus lurninyensis, or another methanogenic organism can provide a quantity significant amount of methane.
    [0006] The present invention therefore consists essentially in the biological production of methane (biogas) by a combination of a methanogenic bacterium and anaerobic bacterium cultivating aerobically in a medium rich in antioxidant components and containing a hydrocarbon source.
    [0007] To this end, the present invention provides a method for producing methane gas in a reactor by co-cultivation in an aerobic atmosphere, preferably ambient air of at least: a first microorganism consisting of an anaerobic bacterium capable of producing hydrogen by fermentation in the presence of a substrate and / or a culture medium comprising or supplemented with hydrocarbon compound (s), in particular starch and / or sugars, and - a second microorganism consisting of an Archaea methanogen capable of producing methane from hydrogen and a substrate and / or culture medium comprising or supplemented with hydrocarbon compound (s), in particular starch and / or sugars, and - a substrate organic and inorganic composition comprising components of culture media capable of allowing the cultivation of the two said first and second anaerobic microorganisms, said culture medium comprising or being supplemented with hydrocarbon compound (s), in particular starch and / or sugars, and being further supplemented with antioxidant compound (s). More particularly, the other culture conditions, in particular temperature, are the appropriate conditions for the culture of said microorganisms. In particular, the temperature must be increased to incubate, if necessary, at a temperature that promotes the growth of said microorganisms, in particular at least 30 ° C. or even 37 ° C. It will be understood that the process according to the present invention does not require the supply of external hydrogen and that the co-culture reactor comprises means for recovering the methane gas produced. Preferably, the first microorganism is first cultured in said substrate and said second microorganism is introduced after said first microorganism has already produced fermentation products and hydrogen. More particularly, said antioxidant compound is preferably selected from ascorbic acid, uric acid, glutathione (γ-L-glutamyl-L-cysteinylglycine). Ascorbic acid is preferred because it is capable at precise doses of allowing culture to a higher oxygen level. More particularly, said antioxidant compound is used at a concentration of 1 μg / ml to 2 mg / ml, or molar concentration of 10-6 M to 10-2 M, preferably at least 1 g / I.
    [0008] Other antioxidant compounds such as sodium hydrosulfide (NaHS) or cysteine are less effective and require higher concentrations. Preferably, said medium comprises a pH regulating buffer substance to adjust the pH from 7 to 7.5.
    [0009] More particularly, said Archaea is an Archaea selected from the following Archae: Methanobrevibacter, Methanosphaera, Methanornassiliicoccus, Methanobacterium, Methanococcus and Methanosaeta. More particularly, said Archaea is an Archaea selected from the following Archae: Methanobrevibacter srnithii, Methanobrevibacter oralis, Methanosphaera stadtrnanae, Methanornassiliicoccus lurninyensis, Methanobacterium beljingense and Methanosaeta con ciii. More particularly, said Archea is Methanobrevibactera srnithll or Methanornassiliicoccus lurninyensis. Strict anaerobic bacteria that is to say they are not able to grow in the presence of oxygen or in concentrations less than 1%, most commonly less than 0.1%, ideally 0%. Among the strict anaerobic bacteria, mention is made more particularly of extracellular bacteria, ie bacteria which can live only outside cells. More particularly, said anaerobic bacterium capable of producing hydrogen is chosen from bacteria of the families Actinobacteria and Bacteroidetes. Preferably, said anaerobic bacterium is of the genus Bacteroides. These bacteria are known in particular for digesting starch by producing hydrogen.
    [0010] More particularly, said anaerobic bacterium is Bacteroides thetaiotaornicron. Actinobacteria, the bacterium Lactococcus lactis, is also mentioned. More particularly, said culture medium comprises the components found in culture base media capable of cultivating an archaea or anaerobic bacterium, comprising at least: several sources of carbon, a source of phosphorus, preferably a phosphate salt, a nitrogen source, preferably an ammonium salt, at least one metal salt selected from K, Mg, Na, Ca, preferably NaCl. More particularly, said culture medium is an acellular medium is selected from an axenic medium consisting of chemical or biological substances defined qualitatively and quantitatively, and an acellular medium comprising a mulate-cell extract or lysate of multicellular tissue.
    [0011] More particularly, said culture medium is a conventional acellular medium of anaerobic bacterium, preferably a medium comprising components selected from a multivellular tissue extract or lysate, an enzymatic digest, in particular an enzymatic digest of casein, soya and / or animal tissue, a peptone, a yeast extract, a sugar such as dextrose or glucose, an NaCl salt and / or Na2PO4. More particularly, said culture medium is a conventional culture medium for anaerobic bacteria such as broth-like heart-brain media, Columbia medium 5% sheep blood or Schaedler medium as described below. Other suitable conventional media are Brucella or Wilkins-Chagren media. Such cell-free culture media are well known to those skilled in the art.
    [0012] In particular, it is possible to use polyvalent culture media for anaerobic microorganisms, in particular Schaedler's medium, said medium being supplemented with hydrocarbon compounds, preferably starch and sugar (s), and said antioxidant compound (s).
    [0013] The inventors have indeed tested different molecules exhibiting antioxidant activity and have discovered that certain antioxidant compounds in certain concentrations have a greater effect on the growth of said bacteria. Other features and advantages of the present invention will emerge more clearly on reading the description which will follow, given in an illustrative and nonlimiting manner, of an exemplary embodiment. To illustrate the invention, the inventors have cultivated archaea methanogens deemed strict anaerobes (known to grow only in the strict absence of oxygen), in an aerobic atmosphere (that is to say in the open air, containing about 16 % oxygen) and in the presence of bacteria deemed strict anaerobic, in culture media of bacteria and archae reputed anaerobic, said culture media being supplemented with antioxidant compounds to support growth in ambient air atmosphere and complemented with hydrocarbon compounds to produce H2 and CH4. 1) Strains used. A methanogenic archaea Methanobrevibacter srnithll strain DSM 861 was obtained from the German collection of microorganisms and cell cultures (DSMZ, Braunschweig, Germany) also deposited ATCC under number ATCC 35061. An archaea Methanornassiliicoccus lurninyensis deposited in the collection The microorganism deposit DSMZ (Germany), in accordance with the Budapest Treaty, under the number DSM 24529 was also tested described in FR124779 (published under number 2 15 990954). Furthermore, a strain of anaerobic bacterium Bacteroides thetaiotaornicron has been obtained through the inventors' "culturomics" study (Lagier JC et al., Microbial culturomics: paradigm shift in the human gut microbiome study, Clin Microbiol Infect 2012; : 1185-93) 20 also available in various deposit collections (CSUR P766 also deposited under the Budapest Treaty to the DSMZ microorganism deposit collection (Germany) on May 19, 2014 under the number DSM 28808, other strains are also available in various deposit collections such as strains DSM 2079, ATCC 29148 and NCTC 10582). Another strain of following anaerobic bacterium was also tested: Lactococcus lactis deposited under the Budapest Treaty at the DSMZ microorganism depot collection (Germany) on May 19, 2014 under the number DSM 28809, also available in various collections of deposit of which the National Collection of cultures of microorganisms CNCM 1-2716. 2) Aerobic culture of anaerobic microorganisms using antioxidants. For their production in sufficient quantity, the two M. srnithll or M. lurninyensis and B. thetaiotaornicron strains were cultured in an anaerobic atmosphere at 37 ° C. in a polyvalent culture medium. Schaedler's medium (Reference 42098, BioMerieux, La Balmes-les-Grottes, France) and the medium referred to as "SAB medium" described in FR 124779 (published under No. 2,990,954) and WO 2013/0044933, which is usually used, were tested. to cultivate human methanogenic archaea and which appears appropriate also for the cultivation of anaerobic bacteria. The Schaedler medium (marketed by Biomerieux, Marcy l'étoile, France) had the following composition for 1 liter: Enzymatic digest of casein 5.6 g Enzymatic digest of soybean meal 1 g Enzymatic digest of animal tissues 5 g yeast 5 g - NaCl 1.7 g - Potassium phosphate 0.82 g - Dextrose 5.82 g - Tris (hydroxymethyl) Aminomethane 3 g - Hemine 0.01 g - L-cysteine 0.4 g The BSA medium used was free of Na25 and L-cysteine and included : NiCl 2 x 6H 2 O (0.07 mg / l), Na 2 MoO 4 x 2H 2 O (0.02 mg / l), Fe 504 x 7H 2 O (0.2 mg / l), MgSO 4 x 7H 2 O (0.01 g / l), K 2 HPO 4 (0.5 g / 1), KH 2 PO 4 (0.5 g / l), KCl (0.05 g / l), CaCl 2 (0.05 g / l), NaCl (1.5 g / l), NH 4 Cl (1 g / l), 1), Na-Acetate (1 g / 1), Yeast Extract (1 g / 1), Biotrypticase (1 g / 1), Widdel Micronutrients Solution (2 ml / 1), Balch Micronutrients Solution (10 ml / l), Resazurin (1 mg / l), Na2Oe03.5H2O (0.015 mg / l), Na2W04.2H2O (0.02 mg / l), NiCl2.6H2O (0.07 mg / l), NaHCO3 (4 g / 1), Na-Formate (0.4 g / 1), Methanol (40mM), Balch's Medium Vitamin Solution (10m1 / 1), Valeric Acid (0.6g / l), Isovaleric Acid (0.6g / l), Acid 2- methylbutyric (0.6 g / l), isobutyric acid (0.6 g / l), 2-methylvaleric acid (0.6 g / l).
    [0014] The trace elements of Balch include NaCl, Fe 504, Zn 504, Mg 504, Mn 504, Co 504, H3B03, NiCl2, Na2MoO4, CaCl2. Widdel trace elements include FeCl2, CoCl2, MnCl2, ZnCl2, H3B03, Na2MoO4, NiCl2 and CuCl2. The vitamins of Balch's medium are listed in Table 6 below and include biotin, folic acid, pyridoxine hydrochloride, thiamine hydrochloride, riboflavin, nicotinic acid, DL-calcium pantothenate, vitamin B12, p-aminobenzoic acid, acid lipoic). This Schaedler medium and this SAB medium were supplemented by the addition of hydrocarbon compounds, namely 1 g / L of rice starch and 1 g / L of glucose (Sigma-Aldrich, Saint-Quentin Fallavier, France). and the addition of anti-oxidant compounds namely complemented by the addition of 1 g / L of ascorbic acid (VWR International, Leuven, Belgium), 0.1 g / L of uric acid and 0.1 g / L of L of glutathione (Sigma-Aldrich, Saint-Quentin Fallavier, France).
    [0015] Resazurin is used as an oxidation-reduction indicator at a concentration of 0.1 mg / ml to control the presence of oxygen (the oxidized resazurin has a pink color, and becomes transparent in the absence of oxygen) . The aerobic culture in ambient air of M. srnithll or M. lurninyensis and B. thetaiotaornicron was carried out in separate containers and in one and the same vessel incubated at 37 ° C. containing the culture medium supplemented by the addition of antioxidant compounds. and carbon source compounds. The pH was adjusted to 7.5 by addition of 10M KOH. Both strains were cultured separately as well as in co-culture, under aerobic conditions and by the inoculation of 105 organisms / ml of each strain with the complemented culture medium according to the present invention and in parallel with the Schaedler or BSA medium supplemented. by the hydrocarbon compounds mentioned above but on the other hand without antioxidant compounds. The positive controls consist of a tube containing the culture medium supplemented above, inoculated anaerobically by 108 microorganisms / L of M. srnithll or M. lurninyensis in the presence of the gas mixture of 80% H2 + 20% CO2 at the same time. two-atmosphere pressure required for optimal growth of methanogenic archaea. The complemented culture medium inoculated anaerobically with 108 microorganisms / L of M. srnithll or M. lurninyensis without this gas mixture was introduced to check the growth of this archaea methanogen without H2. The culture medium supplemented by adding 1 g / L of rice starch and 1 g / L of glucose inoculated anaerobically with 108 cells / L of B. thetaiotaornicron was introduced as a positive control and to verify the production of H2 by B. thetaiotaornicron in anaerobic culture. These checks were carried out in parallel in an ambient atmosphere (aerobic). The non-inoculated culture medium was introduced as a negative control. 3) Detection of growth by gas chromatography. The growth of M. srnithll or M. lurninyensis was evaluated daily by methane production and the growth of B. thetaiotaornicron was evaluated daily by hydrogen production. The measurement of methane and hydrogen was carried out using a GC-8A gas chromatograph (Shimadzu, Champs-sur-Marne, France) equipped with a thermal conductivity detector and a Chromosorb WAW 80/100 column SP100 mesh (Alltech, Carquefou, France). N2 nitrogen at a pressure of 100 kPa was used as the carrier gas. The detector and the injector temperatures were 200 ° C and the column temperature was 150 ° C. 4) Results. 4.1) Controls. Negative controls remained negative with no growth occurring after one week of incubation indicating that the results reported here are not simply the result of contamination by other microorganisms. The positive controls were positive with methane production observed in the anaerobic culture of M. strnithll or M. lurninyensis and with hydrogen production observed in the anaerobic B. thetaiotaornicron culture. There was no detectable methane production in the culture of M. srnithll or M. lurninyensis inoculated alone anaerobically and aerobically without gas mixing. Also, culture of B. thetaiotaornicron inoculated aerobically without antioxidant compounds remained negative and hydrogen was not produced. 4.2) Aerobic co-culture. After incubation for 24 hours at 37 ° C in ambient air (under aerobic conditions), a culture medium without antioxidant compounds retained its pink color indicating the presence of oxygen. The aerobic culture medium with the antioxidant compounds became transparent indicating the absence of oxygen after its reduction by the antioxidant compounds. The culture medium inoculated aerobically with M. srnithll or M. lurninyensis with the antioxidant compounds became transparent, but the culture remained negative and the methane was not produced. The culture medium inoculated aerobically by B. thetaiotaornicron in the presence of antioxidants became transparent and bacterial growth was observed with production of hydrogen.
    [0016] Co-cultures of M. srnithll or M. lurninyensis and B. thetaiotaornicron under aerobic conditions with antioxidant compounds all gave a positive culture for B. thetaiotaornicron with production of hydrogen after a 24 hour incubation. On the other hand, in some experiments, no growth was observed for M. srnithll or M. lurninyensis (although the culture medium became transparent). The inventors have hypothesized that M. srnithll or M. lurninyensis died from exposure to oxygen before the medium was reduced by the antioxidant compounds. Experiments were carried out with the introduction of B. thetaiotaornicron at 0 and M. srnithll or M. lurninyensis added at t0 + 24 hours of incubation. The addition of M. srnithll or M. lurninyensis after 24 hours of incubation allowed in all cases to restore its growth by consuming the hydrogen previously produced by B. thetaiotaornicron in the presence of antioxidant compounds and avoiding a fatal exposure to oxygen. This same experiment was carried out without an antioxidant compound and the culture remained negative for the two strains tested.
    [0017] On the other hand, the anaerobic bacterium Lactococcus lactis DSM 28809 has also been successfully tested in combination with these two archaea. 4.3) Interpretation. These results indicate that it is possible to grow bacteria (known as anaerobic) in ambient air (aerobic condition) in a suitable medium containing a suitable mixture of antioxidants. Under these conditions, anaerobic bacteria produce hydrogen which can then be used in the second time by archaea methanogens for the production of methane.
    [0018] It has been shown that it is possible to produce methane in ambient air, under appropriate conditions of co-cultivation of bacteria and anaerobic methanogens in a culture medium supplemented with carbon source compounds and antioxidant compounds.
    [0019] The introduction of methanogenic archaea into a medium already containing fermentation products and hydrogen is preferable.
    权利要求:
    Claims (15)
    [0001]
    REVENDICATIONS1. Process for producing methane gas by co-cultivation in a reactor in an aerobic atmosphere, preferably ambient air, of at least: a first microorganism consisting of an anaerobic bacterium capable of producing hydrogen by fermentation in the presence of a substrate and / or a culture medium comprising or supplemented with hydrocarbon compound (s), and - a second microorganism consisting of a methanogenic archaea capable of producing methane from hydrogen and a substrate and / or culture medium comprising or supplemented with hydrocarbon compound (s), and - an organic and inorganic substrate comprising culture medium components capable of allowing the cultivation of both said first and second microorganisms, said culture medium comprising or being supplemented with hydrocarbon compound (s), and being additionally supplemented with antioxidant compound (s).
    [0002]
    2. Method according to claim 1, characterized in that firstly culturing said first microorganism in said substrate and introducing said second microorganism after said first microorganism has already produced fermentation products and hydrogen .
    [0003]
    3. Method according to one of claims 1 or 2, characterized in that the (s) said (s) antioxidant compound (s) is (are) chosen from ascorbic acid, uric acid, glutathione, preferably ascorbic acid.
    [0004]
    4. Method according to one of claims 1 to 3, characterized in that said Archaea is Archaea selected from the archaesuivantes: Methanobrevibacter, Methanosphaera, Methanornassiliicoccus, Methanobacteriurn, Methanococcus and Methanosaeta.
    [0005]
    5. Method according to claim 4, characterized in that said archaea is an archaea selected from the following archaeeties: Methanobrevibacter srnithii, Methanobrevibacter oralis, Methanosphaera stadtrnanae, Methanornassiliicoccus lurninyensis, Methanobacterium beijingense and Methanosaeta concilii.
    [0006]
    6. Process according to claim 5, characterized in that said arc hea is Methanobrevibacter srnithii or Methanornassiliicoccus lurninyensis.
    [0007]
    7. Method according to one of claims 1 to 6, characterized in that said anaerobic bacterium capable of producing hydrogen is selected from bacteria Bacteroidetes families and Actinobacteria.
    [0008]
    8. Process according to claim 7, characterized in that said anaerobic bacterium is of the genus Bacteroides.
    [0009]
    9. The method of claim 8, characterized in that said anaerobic bacterium is Bacteroides thetaiotaornicron or lactococcus lactis.
    [0010]
    10. Process according to claim 7, characterized in that said anaerobic bacterium is lactococcus lactis.
    [0011]
    11. Method according to one of claims 6 to 10, characterized in that said organism is selected from the strains of Methanobrevibacter srnithii D5111 861 and the strain Methanornassiliicoccus lurninyensis D5111 24529 and the anaerobic bacterium is selected from the strain Bacteroides thetaiotaornicron D5111 28808 and the strain Lactococcus lactis D5111 28809.
    [0012]
    12. Method according to one of claims 1 to 11, characterized in that said culture medium comprises at least the following components: - several sources of carbon, - a source of phosphorus, preferably a phosphate salt, - a source nitrogen, preferably an ammonium salt, at least one metal salt selected from K, Mg, Na, Ca, preferably NaCl.
    [0013]
    13. Process according to claim 12, characterized in that said antioxidant compound is used at a concentration of 1 mg / l to 2 g / l, preferably at least 1 g / l.
    [0014]
    14. Method according to one of claims 1 to 13, characterized in that said medium comprises a buffer pH regulating substance for adjusting the pH of 7 to 7.5.
    [0015]
    15. Method according to one of claims 1 to 14, characterized in that said medium comprises the components of Schaedler's medium supplemented with hydrocarbon compounds, preferably starch and (s) sugar (s), and said (s) antioxidant compound (s).
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    WO2020102537A1|2018-11-14|2020-05-22|Washington State University|Host-free 'candidatus liberibacter asiaticus' culture|
    法律状态:
    2015-04-22| PLFP| Fee payment|Year of fee payment: 2 |
    2015-10-30| PLSC| Publication of the preliminary search report|Effective date: 20151030 |
    2016-04-22| PLFP| Fee payment|Year of fee payment: 3 |
    2017-06-29| PLFP| Fee payment|Year of fee payment: 4 |
    2018-06-06| PLFP| Fee payment|Year of fee payment: 5 |
    2019-05-23| PLFP| Fee payment|Year of fee payment: 6 |
    2020-05-05| PLFP| Fee payment|Year of fee payment: 7 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1453652A|FR3020379B1|2014-04-23|2014-04-23|PROCESS FOR THE PRODUCTION OF METHANE BY AEROBIC CO-CULTURE OF ANAEROBIC MICROORGANISMS|
    FR1453652|2014-04-23|
    FR1455745A|FR3020380B1|2014-04-23|2014-06-20|PROCESS FOR PRODUCTION OF METHANE BY AEROBIC CO-CULTURE OF ANAEROBIC MICROORGANISMS|FR1455745A| FR3020380B1|2014-04-23|2014-06-20|PROCESS FOR PRODUCTION OF METHANE BY AEROBIC CO-CULTURE OF ANAEROBIC MICROORGANISMS|
    FR1458622A| FR3020378B1|2014-04-23|2014-09-15|USE OF URIC ACID FOR THE CULTURE OF OXYGEN TENSION-SENSITIVE BACTERIA|
    EP15725765.0A| EP3134533B1|2014-04-23|2015-04-20|Method for producing methane by means of aerobic co-culture of anaerobic micro-organisms|
    US15/304,926| US10011852B2|2014-04-23|2015-04-20|Method for producing methane by means of aerobic co-culture of anaerobic micro-organisms|
    PCT/FR2015/051067| WO2015162366A1|2014-04-23|2015-04-20|Method for producing methane by means of aerobic co-culture of anaerobic micro-organisms|
    CN201580021066.1A| CN106459882B|2014-04-23|2015-04-21|Use of uric acid for culturing oxygen tension sensitive bacteria|
    US15/304,887| US10626421B2|2014-04-23|2015-04-21|Use of uric acid for culturing bacteria sensitive to oxygen tension|
    PCT/FR2015/051082| WO2015162377A1|2014-04-23|2015-04-21|Use of uric acid for culturing bacteria sensitive to oxygen tension|
    EP15725773.4A| EP3134508A1|2014-04-23|2015-04-21|Use of uric acid for culturing bacteria sensitive to oxygen tension|
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