References [ 14 ]
Müller J, Friedl T, Hepperle D, Lorenz M & Day JG (2005) Distinction between multiple isolates of Chlorella vulgaris (Chlorophyta, Trebouxiophyceae) and testing for conspecificity using Amplified Fragment Length Polymorphism and its rDNA sequences. Journal of Phycology 41(6): 1236-1247.
Pruvost J, Van Vooren G, Le Gouic B, Couzinet-Mossion A & Legrand J (2011) Systematic investigation of biomass and lipid productivity by microalgae in photobioreactors for biodiesel application. Bioresource Technology 102: 150-158.
Abedini Najafabadi H, Malekzadeh M, Jalilian F, Vossoughi M & Pazuki G (2015) Effect of various carbon sources on biomass and lipid production of Chlorella vulgaris during nutrient sufficient and nitrogen starvation conditions. Bioresource Technology 180: 311-317.
Abedini Najafabadi H, Vossoughi M & Pazuki G (2015) The role of co-solvents in improving the direct transesterification of wet microalgal biomass under supercritical condition. Bioresource Technology 193: 90-96.
Kandilian R, Soulies A, Pruvost J, Rousseau B, Legrand J & Pilon L (2016) Simple method for measuring the spectral absorption cross-section of microalgae. Chemical Engineering Science 146: 357-368.
Malekzadeh M, Najafabadi HA, Hakim M, Feilizadeh M, Vossoughi M & Rashtchian D (2016) Experimental study and thermodynamic modeling for determining the effect of non-polar solvent (hexane)/polar solvent (methanol) ratio and moisture content on the lipid extraction efficiency from Chlorella vulgaris. Bioresource Technology 201: 304-311.
Souliès A, Pruvost J, Castelain C & Burghelea T (2016) Microscopic flows of suspensions of the green non-motile Chlorella micro-alga at various volume fractions: Applications to intensified photobioreactors. Journal of Non-Newtonian Fluid Mechanics 231: 91-101.
Kandilian R, Pruvost J, Artu A, Lemasson C, Legrand J & Pilon L (2016) Comparison of experimentally and theoretically determined radiation characteristics of photosynthetic microorganisms. Journal of Quantitative Spectroscopy and Radiative Transfer 175: 30-45.
Souliès A, Legrand J, Marec H, Pruvost J, Castelain C, Burghelea T & Cornet JF (2016) Investigation and modeling of the effects of light spectrum and incident angle on the growth of Chlorella vulgaris in photobioreactors. Biotechnology Progress 32: 247-261.
DOI: 10.1002/btpr.2244
Taleb A, Kandilian R, Touchard R, Montalescot V, Rinaldi T, Taha S, Takache H, Marchal L, Legrand J & Pruvost J (2016) Screening of freshwater and seawater microalgal strains in fully controlled photobioreactors for biodiesel production. Bioresource Technology 218: 480-490.
Goh BHH, Ong HC, Cheah MY, Chen WH, Yu KL, Mahlia TMI (2019) Sustainability of direct biodiesel synthesis from microalgae biomass: A critical review Renewable and Sustainable Energy Reviews 107: 59-74.
Aghilinategh M, Barati M & Hamadanian M (2019) Supercritical methanol for one put biodiesel production from Chlorella vulgaris microalgae in the presence of CaO/TiO2 nano-photocatalyst and subcritical water Biomass and Bioenergy 123: 34-40.
Castillo LA, Valadés-Pelayo PJ, Avila-Paredes HJ, Cabello JJ & Balbuena A (2023) Methodology for the fast direct estimation of spectral radiative transport properties in microalgae photobioreactors Chemical Engineering Journal 458: 141462.
Chakraborty S, Sirotiya V, Rai A, Varjani S & Vinayak V (2023) Catalyst in algal refinery: A way towards production of high-quality biofuel Sustainable Chemistry and Pharmacy 33: 101092.
Division/Phylum: Chlorophyta Class: Trebouxiophyceae Order: Chlorellales
Note: for strains where we have DNA barcodes we can be reasonably confident of identity, however for those not yet sequenced we rely on morphology
and the original identification, usually made by the depositor. Although CCAP makes every effort to ensure the correct taxonomic identity of strains, we cannot guarantee
that a strain is correctly identified at the species, genus or class levels. On this basis users are responsible for confirming the identity of the strain(s) they receive
from us on arrival before starting experiments.
For strain taxonomy we generally use AlgaeBase for algae and
Adl et al. (2019) for protists.
Culture media, purity and growth conditions:
Medium:
3N-BBM+V;
Bacteria present; maintained by serial subculture and cryopreserved;
| Attributes | |
| Authority | Beyerinck [Beijerinck] 1890 |
| Isolator | von Witsch (1946/7) |
| Collection Site | Göttingen, Germany |
| Axenicity Status | Bacteria present |
| Area | Europe |
| Country | Germany |
| Environment | Freshwater |
| GMO | No |
| In Scope of Nagoya Protocol | No |
| ABS Note | Collected pre Nagoya Protocol. No known Nagoya Protocol restrictions for this strain. |
| Collection Date | pre 1950 |
| Pathogen | Not pathogenic: Hazard Class 1 |
| Strain Maintenance Sheet | SM_GeneralFreshwaterGreens.pdf |
| Toxin Producer | Not Toxic / No Data |
| Type Culture | No |
| Taxonomy WoRMS ID | 532029 |
| Equivalent Strains | SAG 211-19 |
Related Products
CCAP FA3N-C
3N-BBM+V Medium
CONCENTRATED STOCKS
Non-sterile concentrated stocks to make up 5 litres of 3N-BBM+V medium. 3N-BBM+V medium is used for
CCAP FA3N-P
3N-BBM+V Medium
1 LITRE PREMADE
1 litre of sterile, ready to use, 3N-BBM+V medium. 3N-BBM+V medium is used for culturing freshwater