Page last updated: 2024-08-21

cellobiose and sorbitol

cellobiose has been researched along with sorbitol in 7 studies

Research

Studies (7)

TimeframeStudies, this research(%)All Research%
pre-19900 (0.00)18.7374
1990's2 (28.57)18.2507
2000's0 (0.00)29.6817
2010's5 (71.43)24.3611
2020's0 (0.00)2.80

Authors

AuthorsStudies
Clorius, JH; Friedrich, EA; Maier-Borst, W; Schilling, U; Schrenk, HH; Sinn, H1
Lund, M; Penttilä, ME; Saloheimo, M1
Binnemans, K; De Vos, DE; Ignatyev, IA; Mertens, PG; Van Doorslaer, C1
Gargouri, A; Saibi, W1
Deng, W; Liu, M; Wang, Y; Zhang, Q1
Chen, J; Chen, L; Huang, J; Huang, X; Ma, L; Wang, S1
Li, Y; Niu, W; Tan, M; Tsubaki, N; Wang, D; Wu, M; Zheng, X1

Other Studies

7 other study(ies) available for cellobiose and sorbitol

ArticleYear
Design of compounds having enhanced tumour uptake, using serum albumin as a carrier--Part II. In vivo studies.
    International journal of radiation applications and instrumentation. Part B, Nuclear medicine and biology, 1992, Volume: 19, Issue:6

    Topics: Animals; Cellobiose; Drug Carriers; Female; Iodine Radioisotopes; Neoplasm Transplantation; Ovarian Neoplasms; Radionuclide Imaging; Rats; Rats, Inbred Strains; Serum Albumin; Sorbitol; Tissue Distribution; Tyramine

1992
The protein disulphide isomerase gene of the fungus Trichoderma reesei is induced by endoplasmic reticulum stress and regulated by the carbon source.
    Molecular & general genetics : MGG, 1999, Volume: 262, Issue:1

    Topics: Amino Acid Sequence; Base Sequence; Carrier Proteins; Cellobiose; Cellulose; Chromosomes, Fungal; Culture Media; DNA, Complementary; Endoplasmic Reticulum; Endoplasmic Reticulum Chaperone BiP; Enzyme Induction; Fungal Proteins; Gene Expression Regulation, Fungal; Genes, Fungal; Glucose; Heat-Shock Proteins; HSP70 Heat-Shock Proteins; Molecular Chaperones; Molecular Sequence Data; Protein Disulfide-Isomerases; Protein Folding; Sequence Analysis, DNA; Sequence Homology, Amino Acid; Sorbitol; Trichoderma

1999
Reductive splitting of cellulose in the ionic liquid 1-butyl-3-methylimidazolium chloride.
    ChemSusChem, 2010, Volume: 3, Issue:1

    Topics: Biocatalysis; Cellobiose; Cellulose; Cycloheptanes; Ethyl Ethers; Hydrogen; Imidazoles; Ionic Liquids; Models, Chemical; Oxidation-Reduction; Ruthenium; Solubility; Sorbitol; Temperature

2010
Hydroxyl distribution in sugar structure and its contributory role in the inhibition of Stachybotrys microspora β-glucosidase (bglG).
    Carbohydrate research, 2011, Sep-27, Volume: 346, Issue:13

    Topics: beta-Glucosidase; Cellobiose; Deoxyglucose; Enzyme Inhibitors; Fructose; Fungal Proteins; Galactose; Glucose; Maltose; Mannose; Sorbitol; Stachybotrys; Structure-Activity Relationship; Xylose

2011
Polyoxometalate-supported ruthenium nanoparticles as bifunctional heterogeneous catalysts for the conversions of cellobiose and cellulose into sorbitol under mild conditions.
    Chemical communications (Cambridge, England), 2011, Sep-14, Volume: 47, Issue:34

    Topics: Cellobiose; Cross-Linking Reagents; Metal Nanoparticles; Ruthenium; Sorbitol; Tungsten Compounds

2011
Conversion of cellulose and cellobiose into sorbitol catalyzed by ruthenium supported on a polyoxometalate/metal-organic framework hybrid.
    ChemSusChem, 2013, Volume: 6, Issue:8

    Topics: Catalysis; Cellobiose; Cellulose; Metal Nanoparticles; Models, Molecular; Molecular Conformation; Organometallic Compounds; Ruthenium; Sorbitol

2013
Pt nanocatalysts supported on reduced graphene oxide for selective conversion of cellulose or cellobiose to sorbitol.
    ChemSusChem, 2014, Volume: 7, Issue:5

    Topics: Biofuels; Catalysis; Cellobiose; Cellulose; Graphite; Microscopy, Electron, Transmission; Molecular Structure; Nanoparticles; Oxidation-Reduction; Oxides; Particle Size; Platinum; Sorbitol; Surface Properties

2014