List of Publications (az 1996-ban megjelent ICS
alapján)
1. Horváth I., Gadó I., Szentirmai
A., 1958. Production of oxytetracycline in synthetic
medium. Acta Microbiol..Acad. Sci. Hung. 5 : 317-327
2. Horváth I.,
Bajusz S., Szentirmai A., 1959. Inhibitory
action of amino acid esters on the production of extracellulare amylase by Penicilliun chrysogenum. Nature 183:477
Impact factor: 28.417
3. Horváth I.,
Gadó I., Szentirmai A., 1959. Formation of
isoleucine in culture media containing threonine. J. Bacteriol. 78 /2 : 293
Impact factor: 3.889
4. Horváth I., Szentirmai
A., 1959 Inhibitory effect of fungistatic
antibiotics in the production of amylase by Penicillium
chrysogenum. Nature 184 : 57-58
Impact factor: 28.417
5. Gláz R.T.,
Scheiber E., Gyimesi J., Horváth I., Steczek K., Szentirmai A., Bohus G., 1959. A new trichotecinlike antifungal
antibiotic. Nature 184:908
Impact factor: 28.417
6. Horváth I., Szentirmai
A., Bajusz S., Parragh É., 1960. The production of
the inductive amylase by Penicillium
chrysogenum. Acta Microbiol. Acad. Sci. Hung. 7 :
19-29
7. Horváth I., Szentirmai
A., 1960. The mode of inhibition of induced
amylase synthesis by nystatin. Antibiot. Chemother. 10/5 :
303-305
Impact factor: 0.870
8. Horváth I.,
Gadó I., Szentirmai A., 1961. Possible causes
for production of isoleucine by Streptomyces
rimosus. Nature 192 : 641-642
Impact factor: 28.417
9. Gadó I., Szentirmai
A., Steczek K., Horváth I., 1961. Metabolic
studies with Streptomyces rimosus.
Acta Microbiol. Acad. Sci. Hung. 8/3 :291-302
10. Horváth I.,
Gadó I., Szentirmai A.,1962. Valine and
isoleucine metabolism of Streptomyces
rimosus. Acta Microbiol. Acad. Sci. Hung. 9 :
11-22
11. Szentirmai A., Horváth I., 1962. L-Serine deaminase of Streptomyces rimosus. Acta Microbiol.
Acad. Sci. Hung. 9 : 23-30
12. Szentirmai A., Horváth I., 1962. L-threonine deaminase of Streptomyces rimosus. Acta Microbiol.
Acad. Sci. Hung. 9 : 31-37
13. Szentirmai A., Braun P., Horváth I., Hauk M., 1962. A rapid
screening test for determination of total alpha amino acid in urine and serum.
Clin. Chim. Acta 7 : 459-462
Impact factor: 1.045
14. Horváth I., Szentirmai
A., 1962. Glucose catabolism of Streptomyces rimosus. Acta Microbiol.
Acad. Sci. Hung. 9 :
105-116
15. Braun P., Hauk
M., Horváth I., Szentirmai A., 1962.
Diuretikumok hatása a szérum és vizelet aminosav tartalmára: szűrővizsgálatra
alkalmas gyors módszer össz-alfa aminonitrogén meghatározására. Orv. Hetil. 103:1933
16. Horváth I.,
Varga J.M., Szentirmai A., 1964. The control of
isoleucine and valine metabolism in Pseudomonas
aeruginosa and Escherichia coli. J .Gen.
Microbiol. 34 : 241
Impact factor: 2.503
17. Bérdy J.,
Horváth I., Szentirmai A., 1964. Antibiotics
produced by Streptomyces II. The
tautomeric transformation of xanthomycin. Z. Allg. Mikrobiologie 4 / 3 : 232-235
Impact factor: 0.490
18. Gyimesi J.,
Horváth I., Szentirmai A., 1964. Antibiotics
produced by Streptomyces V. A new antibiotics K-358. Z. Allg. Mikrobiologie 4/4 : 269-272
Impact factor: 0.490
19. Szentirmai A., 1964. Production of penicillin acylase. Appl.
Microbiol. 12/3 : 185-187
Impact factor: 1.325
20. Szentirmai A., 1966. Properties of Penicillin acylase isolated from
Escherichia coli. Acta Microbiol. Acad. Sci. Hung. 12 : 395-405
21. Szentirmai A.,1966. Studies of penicillin acylase from Escherichia coli. Antibiotics. Herold,
Ed:Gabriel Butterworths Co. Ltd.,
p. 529.
22. Horváth I., Szentirmai
A., Zsadányi J., 1967. Regulation of valine and
isoleucine biosynthesis in Streptomyces
rimosus. Acta Microbiol. Acad. Sci. Hung 13 :
349-356
23. Horváth I., Szentirmai
A., Zsadányi J., 1967. Induced phenotypic
resistance to valine in Mycobacterium
pellegrino. J. Bacteriol. 94 / 4 : 850-853
Impact factor: 3.889
24. Szentirmai A., Umbarger H.E., 1968. Isoleucine and valine
metabolism of Escherichia coli. XIV.
Effect of Thiaisoleucine. J. Bacteriol. 95/3 :
1666-1671
Impact factor: 3.889
25. Szentirmai A., Szentirmai M., Umbarger H.E., 1968. Isoleucine and
valine metabolism of Escherichia coli
XV. Biochemical properties of mutants resistant to thiaisoleucine. J.
Bacteriol. 95/3 :
1672-1679
Impact factor: 3.889
26. Szentirmai A., Horváth I., 1969. Properties of acetohydroxyyacid
synthetase in Mycobacterium pellegrino.
Acta Microbiol. Acad. Sci. Hung 16 : 337-347
27. Szentirmai A., Horváth I., 1970. Properties of threonine deaminase
in Mycobacterium pellegrino. Acta
Microbiol. Acad. Sci. Hung. 17 : 17-27
28. Szentirmai A., Horváth I., Zsadányi J., 1970 Properties of
acetohydoxyacid synthetase in Streptomyces
rimosus. Acta Microbiol. Acad. Sci. Hung. 17 :
105-115
29. Horváth I.,
Holloway B.W., Széll V., Szentirmai A., 1972.
Phenotypic derepression of enzymes of the isoleucine valine pathway by
isoleucine in Pseudomonas aeruginosa. Acta Microbiol. Acad. Sci. Hung. 19 : 251
30. Szabó Gy., Magyar Zs. Szentirmai A.,
Jakab F., Mihály K. 1975. Az epealkotóelemek megjelenése a vérben és a
nyirokban a közös epevezeték elzáródása után. Kisérletes Orvostud. 27 : 414‑421
31. Szabó Gy.,
Magyar Zs., Szentirmai A., Jakab F., Mihály K.,
1975. Bile constituents in blood and lymph during biliary II. The absorption
and transport of bile acids and bilirubin obstruction. Lymphology 8 : 36-42
Impact factor: 0.307
32. Szentirmai A., Szeleczky Z., Tömörkény E., 1975. Properties of
hydroxysteroid oxidoreductase isolated from yeast. Acta Microbiol. Acad. Sci.
Hung. 22:463‑471
33. Kerényi G., Szentirmai
A., Natonek M., 1975. Properties of D-5-3-b-hydroxysteroid
oxidoreductase isolated from Streptomyces
griseocarneus. Acta Microbiol. Acad. Sci. Hung. 22:487‑496
34. Szentirmai A., Tömörkény E., Makk N., Natonek M., 1975. Production
of 13-alkyl-3-methoxy-8,14-seco-1,3,5(10),9(11)-gonatetraen-17-ones
and 13-alkyl-3-methoxy-8,14-seco-1,3,5(10),9(11)- gonatetraen-17b-ol-14-ones by
microbial enzymes. Acta Microbiol. Acad. Sci. Hung. 22:471‑479
35. Szentirmai A., Horváth I., 1976. Regulation of branched‑chain
aminoacid biosynthesis. Acta Microbiol.
Acad. Sci. Hung. 23 : 137-149
36. Jakab F.,
Szabó Gy., Mihály K., Szentirmai A., 1976.
Epealkotóelemek retenciója és regurgitációja obstrukciós icterusban. Kisérletes
Orvostud. 28 : 254-264
37. Makk N.,
Tömörkény E., Szentirmai A., Tóth G., Horváth
Gy., Kajtár M., 1976. Vizsgálatok a 19-norszteroidok totálszintézisében. Kém.
Közl. 46 : 23-40
38. Tömörkény E.,
Makk N., Tóth G., Szabó A., Szentirmai A.,
1976. 13-alkyl-3-methoxy-8,14-seco-1,3,5(10),9(11)-gonatetraene
derivatives. I. Synthesis of 14,17-dihydroxy
derivatives. Acta Chim. Acad. Sci. Hung. 98 : 81-90
39. Szentirmai A., 1977. Mikrobiológiai szteroid transtformációs
kutatások Magyarországon. Magyar Kémikusok Lapja 32/3 :
136-143
40. Szentirmai A., Kerényi G., Natonek M., 1978. Immobilization of 3-b-hydroxysteroid
dehydrogenase isolated from Streptomyces
griseocarneus. Enzyme Engineering Vol 4. Plenum press N.Y.,
pp. 155‑157
41. Szentirmai A., 1983. Mikrobiológiai eljárások a biotechnológia
szolgálatában. Magyar Tudomány 11: 838-843
42. Szentirmai A.,1984. A fermentációs ipar kapcsolata a biokémiai és
mikrobiológiai alapkutatással. Magyar Kémikusok Lapja 39: 237-241
43. Szentirmai A., Szeleczky Z., Büki K., 1986. Overproduction of
metabolites by physiological methods. Biological, Biochemical and Biomedical
Aspects of Actinomycetes. Ed: Szabó G., Biró S.,
Goodfellow M. Symposia Biologica Hungarica Vol. 32 page 161‑169
44. Szentirmai A., 1986 Biotechnológia a vegyiparban és a biológiai
eredmények szabadalmi oltalma. Magyar Kémikusok Lapja 41/10 :
361‑370
45. Szentirmai A., 1987. The Janus‑face of Biotechnology; Science
and Profit‑making. Acta Microbiol. Acad Sci. Hung. 35 :
123
46. Szentirmai A., 1990. Microbial physiology of sidechain degradation
of sterols. J. Ind. Microbiol. 6 : 101‑116
Impact factor: 0.819
47. Sztaricskai
F., Dinya Z., Batta Gy., Szállás E., Szentirmai A.,
Fodor A., 1992. Anthraquinones produced by Enterobacters and nematodes. Acta
Chim. Hung. 129 /5 : 697‑707
48. Kozma J.,
Bartók G., Szentirmai A. 1993. Fructose‑2,6‑bisphosphate level and beta‑lactam formation
in Penicillium chrysogenum. J. Basic Microbiol. 33/1 : 27-34
Impact factor: 0.490
49. Pócsi I.,
Pusztahelyi T., Bogáti M., Szentirmai A., 1993.
The formation of N-acetyl-b-glucoaminidase(NAG) is repressed by glucose
in Penicillium chrysogenum. J.Basic Microbiol. 33/4 : 259‑267
Impact factor: 0.490
50. Gyüre I.,
Lenkey B., Szentirmai A. 1993. Propionyl‑CoA
elimination may be a rate‑determining step of selective cleavage of
sterol side chain. Biotechnol. Letters 15/9 : 925‑930
Impact factor: 0.963
51. Oláh A., Papp Zsuzsanna, Szentirmai A., 1993. Inulin
formation of penicillin producing industrial Penicillium chrysogenum strains. Acta Microbiol. Hung. 40/4 : 379-386.
52. Emri T.,
Bartók G., Szentirmai A., 1994. Regulation of
specific activity of glucose-6-phosphate dehydrogenase and 6-phospho-gluconate
dehydrogenase in Penicillium chrysogenum.
FEMS Microbiol. Letters 117 : 67‑70 Impact factor: 1.735
53. Nógrády N.,
Pócsi I., Szentirmai A., 1995. Cyclodextrin
glycosyltransferase may be the only starch-degrading enzyme in Bacillus macerans. Biotechnol. Appl.
Biochem. 21 : 233-243.
Impact factor: 1.078
54.Szentirmai Attila.1996. Milyen pedagógust igényel a jövő
iskolája -Közoktatásunk és a magyar jövőkép. Új pedagógiai szemle, 46:10 (1996), p.
42-55
55. Karaffa L.,
Sándor E., Kozma J., Szentirmai A. 1996.
Cephalosporin C production, morphology and alternative respiration of Acremonium chrysogenum in
glucose-limited chemostat. Biotechnol. Letters 18/6 :
701-706.
Impact factor: 0.963
56. Bogáti M.,
Pócsi I., Maticsek J., Boross P., Tőzsér J., Szentirmai A.
1996. NADP-specific glutamate dehydrogenase of Penicillium chrsogenum has a homohexamer structure. J. Basic.
Microbiol. 36/5 : 371-375.
Impact factor: 0.490
57. Nógrády N.,
Pócsi I., Katona É., Jeney V., Boross P., Tőzsér J., Fachet J., Szentirmai A. 1996. Soluble cell-bound and extracellular
cyclodextrin glycosyltransferases of Bacillus
macerans show identical enzymological characteristics and antigenicity. J.
Basic Microbiol. 36/5 : 335-340.
Impact factor: 0.490
58. Pusztahelyi T.,
Pócsi I., Kozma J., Szentirmai A., 1997. Aging
of Penicillium chrysogenum cultures
under carbon starvation:I: morphological changes and
secondary metabolite production. Biotechnol. Appl. Biochem. 25
: 81-86Impact factor: 1.078
59. Pusztahelyi
T., Pócsi I., Szentirmai A., 1997. Aging of Penicillium chrysogenum cultures under
carbon starvation:II: protease and N-acetyl-b-D-hexosaminidase
production. Biotechnol. Appl. Biochem. 25 : 87-93
Impact factor: 1.078
60. Karaffa L.,
Sándor E., Kozma J., Szentirmai A., 1997.
Methionine enhances sugar consumption, fragmentation, vacuolation and
cephalosporin-C production in Acremonium chrysogenum Process
Biochem. 32/6 : 495-499 Impact
factor: 0.790
61. Emri T., Pócsi
I., Szentirmai A. 1997. Glutathione metabolism
and protection against oxidative stress caused by peroxides in Penicillium chrysogenum. Free radical
Biology & Medicine. 25/5 : 809-814
Impact factor: 3.783
62.
Emri T., Pócsi I., Szentirmai A. 1997.
Phenoxyacetic acid induces glutathione-dependent detoxification and depletes
the glutathione pool in Penicillium
chrysogenum. J.Basic Microbiol. 37/3 : 181-186
Impact factor: 0.490
63. Szállás E.,
Koch C., Fodor A., Burghardt J., Buss O., Szentirmai
A., Nealson K.H., Stackebrandt E. 1997. Phylogenetic Evidence for the
Taxonomic Heterogeneity of Photorhabdus
luminescens. Intern. Journal of Systematic Bacteriology .
47/2: 402-407
Impact factor:3.929
64. Pócsi I., Nógrády N., Szentirmai A.,
1998. Assay for Simultaneous Determination of ß-Cyclodextrin Glycosyltransferase
(ß-CGTase) and Amylase. Starch/Stärke 50 : 36-38
Impact factor: 0.599
65. Pócsi I., Nógrády N., Lipták
A., Szentirmai A. 1998. Cyclodextrins are
likely to induce cyclodextrin glycosyltransferase (CGTase) production in Bacillus macerans. Folia Microbiol., 43/1 : 71-74
Impact factor: 0.225
66. Nógrády N., Pócsi I., Paffard S.M., Katona
É., Miles R.J., Balázs A., Sándor E., Fachet J., Proce
R.G., Szentirmai A. 1998. Development of ELISA and enzyme-linked
immunofiltration assay (ELIFA) methods for monitoring cyclodextrin
glycoyltransferase (CGTase) production and bacterial growth in Bacillus macerans batch cultures. J. Biotechnol. 60 :
15-22
Impact factor:1.445
67. Emri T., Pócsi I., Szentirmai
A. 1998. Changes in glutathione (GSH) metabolism
of Penicillium chrysogenum grown on
different nitrogen, sulphur and carbon sources. J. Basic Microbiol. 38/1 : 3-8
Impact factor: 0.490
68. Sándor E., Karaffa L., Krahe
M., Märkl H., Szentirmai A.1998. Cultivation of
Acremonium chrysogenum to high cell
density in a dialysis reactor.
Membrántechnika 2/1 : 3-11
69. Völgyi A.,
Fodor A., Szentirmai A., Forst S.
1998. Phase variation in Xenorhabdus
nematophilus. Appl. Environm. Microbiol. 64: 1188-1193
Impact factor: 3.129
70. Sándor E.,
Pusztahelyi T., Karaffa L., Karányi Zs., Pócsi I., Biró S., Szentirmai A., Pócsi I. 1998. Allosamidin inhibits the
fragmentation of Acremonium chrysogenum
but does not influrnce the cephalosporin-C production of the fungus FEMS
Microbiol. Lett 164: 231-236
Impact factor: 1.735
71. Ribar B., Szentirmai A. 1999 Malachit green treatment of industrial
Penicillium chrysogenum protoplasts
results in increased penicillin-V formation 21: J. Ind. Microbiol & Biotechnol 21:
311-314
Impact factor : 0,819
72. Karaffa L.,Sándor E.M.,
Kozma J., Kubicek C., Szentirmai A. 1999 The role of the
alternative respiratory pathway in the stimulation of cephalosporin C formation
by soybean oil in Acremonium
chrysogenum. Applied Microbiology
and Biotechnology 51:633-638
Impact factor: 1,525
73. Emri T Pócsi
I., Szentirmai A. 1999. Analysis of the
oxidative stress response of Penicillium
chrysogenum to menadione. Free Radic. Res.30:
125-132
Impact factor: 2.188
74. Emri T., Sámi
L., Szentirmai A., Pócsi I. 1999 Co-ordination of the nitrate and nitrite
assimilation, the glutathione and free radical metabolisms, and the pentose
phosphate pathway in Penicillium
chrysogenum J. Basic Microbiol. 39
(2) 109-115
75.
Sándor E., Karaffa L., Gopal CP., Pócsi I., Thomas C. R., Szentirmai A. 2000 Assesment of the metabolic activity of Acremonium chrysogenum using Acridine
Orange. Biotechnol. Lett. 22:693-697
76.
Nagy Z., Kiss T., Szentirmai A., Biró S. 2001.
ß-Galactosidase of Penicillium
chrysogenum:Production, Purification, and
Characterization of the Enzyme. Protein Expression and Purification 21: 24-29
77.
Karaffa L., Váczy K., Sándor E., Bíro S., Szentirmai A.,
Pócsi I, 2001 Cyanide resistant
alternative respiration is strictly correlated to intracellular peroxid levels
in Acremonium
chrysogenum Free Rad. Res 34: 405-416
78. Pocsi I, Emri T, Sami L, Leiter E, Szentirmai A. 2001 The
glutathione metabolism of the beta-lactam producer filamentous fungus Penicillium chrysogenum. Acta Microbiol
Immunol Hung 2001;48(3-4):393-411.
79. Karaffa L, Sandor E, Fekete
E, Szentirmai A. 2001 The biochemistry of
citric acid accumulation by Aspergillus
niger. Acta Microbiol Immunol Hung. 2001;48(3-4):429-40.
80. Nagy Z, Keresztessy Z, Szentirmai A,
Biro S. 2001 Carbon source regulation of
beta-galactosidase biosynthesis in Penicillium
chrysogenum. J Basic Microbiol. 2001;41(6):351-62.
Impact factor: 0.490
81.
Sándor E., Juhász A., Szentirmai A., Karaffa L. 2001 A metabolikus
aktivitás becslése Akridinnarancs fluoreszcens festékkel (Abstract in English).
Acta Biologica Debrecina, 22:
69-75.
82.
Fekete E., Karaffa L., Sándor E., Seiboth B., Szentirmai A.,
Kubicek C.P. 2001 ß-galactosidase formation in Aspergillus nidulans. Mededelingen
Faculteit Landbouw-kundige en Toegepaste Biologische Wetenschappen Universiteit
Gent 66/3a: 285-287.
83. Karaffa L, Fekete E, Sandor E, Sepsi A,
Seiboth B, Szentirmai A, Kubicek CP.
2002 Carbon catabolite repression in the regulation of
beta-galactosidase activity in Aspergillus
nidulans. Acta Microbiol Immunol Hung. 2002;49(2-3):261-5.
84. Fekete E, Karaffa L, Sandor
E, Seiboth B, Biro S, Szentirmai A, Kubicek CP.
2002 Regulation of formation of the intracellular ß-galactosidase activity of Aspergillus nidulans. Arch Microbiol.
2002 179(1):7-14.
Impakt faktor: 2.135
85. Karaffa L,
Sandor E, Fekete E, Kozma J, Szentirmai A, Pocsi I. 2003 Stimulation of
the cyanide-resistant alternative respiratory pathway by oxygen in Acremonium chrysogenum correlates with
the size of the intracellular peroxide pool. Can J Microbiol. 2003
Mar;49(3):216-20.
Impakt faktor: 1.150
86. Fekete E, Karaffa L, Sandor
E, Banyai I, Seiboth B, Gyemant G, Sepsi A, Szentirmai
A, Kubicek CP. 2004 The alternative D-galactose degrading
pathway of Aspergillus nidulans
proceeds via L-sorbose. Arch Microbiol. 2004 Jan;181(1):35-44.
Impakt
faktor: 2.13
87. Ilyes H, Fekete E, Karaffa
L, Fekete E, Sandor E, Szentirmai A, Kubicek
CP. 2004 CreA-mediated carbon catabolite
repression of beta-galactosidase formation in Aspergillus nidulans is growth rate dependent. FEMS Microbiol Lett.
235(1):147-51.
Impakt faktor: 2.057
88.
Karaffa L., Fekete E., Gamauf C., Szentirmai A.,
Kubicek C.P., Seiboth B. 2006 D-Galactose
induces cellulase gene expression in Hypocrea jecorina at low growth
rates.Microbiology-SGM, 152:1507-1514. Impakt faktor: 3.173
List
of patents
1. [148960 14.02.59] New process for production
of antifungal antibiotics
2. [148961 16.05.59] Process for production of
new antifungal type antibiotics
3. [148963 16.05.59] Process for the production
of highly active antibiotics
4. [150018 17.05.61] Process for an increased
production of nystatin by Streptomyces
noursei
5. [150473 14.04.61] Process for production of
neomycin
6. [150474 14.04.61] Process for highly
purified neomycin production
7. [150782 14.04.61] Method for production of
6-aminopenicillanic acid
8. [156139 25.08.67] Process for the production
of candicidin by microbial way
9. [159745 02.09.70] Method elaborated for the
production of 13-alkyl-3-methoxy-17-hydroxy-8,14-
-secogona-1,3,5(10),9(11)-tetraene-14-one
10. [163274 01.09.71] Process for the
production of 17b,21-dihydroxy-pregna-1,4-diene 17-acetate
11. [164050 30.12.71]
Process for production of 13b-alkyl-3-methoxy-8,14-secogona-1,3,5(10), 9(11)-
-tetraenes,
which has hydroxyl or oxo group in ring D
12. [164431 12.01.72]
Process for the production of 17b-hydroxy-17a-ethynylestra-4-ene-3-one
hydroxylated derivatives
13. [165689 24.04.72]
Process to prevent lactonization in the microbial production of
androsta-1,4-diene--3,17-dione
14. [168774 16.08.72]
Method for the production of rac-13b-ethyl-3-methoxy-8,14-secogona-1,3,5(10),
9(11)-tetraene-17b-ol-14-one
15. [164517 25,08.72]
Process for the optical antipods of (+)7-syn-benzyloxymethyl-norborn-2-ene-5-one
16. [164434 31.12.72]
Process for the production of 13b-alkyl-3-methoxy-8,14-secogona-1,3,5(10),9(11)--tetraene-14a,17b-dihydroxy
17-acetate derivatives
17. [165545 31.12.72]
Method for the production of 13b-alkyl-3-methoxy-8,14-secogona-1,3,5(10),9(11)--tetraene-14b-hydroxy-17-oxo
compounds
18. [167078 18.01.73]
Novel method for the production of 13b-alkyl-3-methoxy-8,14-secogona-
-1,3,5(10),9(11)-tetraene-14-one derivatives by microbial way
19. [168775 31.01.73]
Process for the production of rac-13b-ethyl-3-methoxygona-1,3,5(l0),8,14-pentaene-17-ol.ac
20. [170147 31.01.73]
Process for the production of rac-13b-ethyl-3-methoxy-8,14-secogona-1,3,5(l0),8-tetraene-17-b-ol-14-one
21. [170004 02.06.75]
Process for glucose-fructose isomerase production
22. [175474 23.05.78] New microbial process for
the production of 12-b-hydroxy-cardenolides
23. [175601 11.08.78]
Microbial process for the production of secondary glycoside from primary
digitalis glycoside
24. [176104 09.06.78]
New method for the microbial resolution of rac-13b-alkyl-3-methoxy-17b-hydroxy-gonaenes
25. [210355 08.05.90] Fast
method for selection of microorganisms for
biotransfomation of water unsoluble compounds