Correction to “Production of Tartrates by Cyanide-Mediated Dimerization of Glyoxylate: A Potential Abiotic Pathway to the Citric Acid Cycle
This article is a guided pedagogical approach, devoted to postgraduate students specializing in bio...
In 1937, Sir H. A Krebs first published the Citric Acid Cycle, a unidirectional cycle with carboxyli...
Correction to “Synthesis and Application of Substituted 1,16-Dihydroxytetraphenylenes in Catalytic A...
ABSTRACT: An abiotic formation of meso- and DL-tartrates in 80 % yield via the cyanide-catalyzed dim...
An abiotic formation of <i>meso</i>- and dl-tartrates in 80% yield via the cyanide-catalyzed dimeriz...
A cycle remains a cycle only as long as the spokes of the wheel are not stolen. To keep the citric a...
Correction to “Merochlorins A–D, Cyclic Meroterpenoid Antibiotics Biosynthesized in Divergent Pathwa...
The citric acid cycle forms a major metabolic hub and as such it is involved in many disease states ...
Correction to “Palladium-Catalyzed Chemo- and Enantioselective Oxidation of Allylic Esters and Carbo...
<p>In the urea cycle: ammonia and bicarbonate form carbamoylphosphate via carbamoyl phosphate synthe...
Correction to “Manganese Catalyzed Dehydrogenative Synthesis of Urea Derivatives and Polyureas
Although cyanide’s biological effects are pleiotropic, its most obvious effects are as a metabolic p...
Correction to “Constructing Quaternary Stereogenic Centers Using Tertiary Organocuprates and Tertiar...
Correction to “Design, Development, Mechanistic Elucidation, and Rational Optimization of a Tandem I...
Significant metabolic changes occur in inflammation to respond to the new energetic needs of cells. ...
This article is a guided pedagogical approach, devoted to postgraduate students specializing in bio...
In 1937, Sir H. A Krebs first published the Citric Acid Cycle, a unidirectional cycle with carboxyli...
Correction to “Synthesis and Application of Substituted 1,16-Dihydroxytetraphenylenes in Catalytic A...
ABSTRACT: An abiotic formation of meso- and DL-tartrates in 80 % yield via the cyanide-catalyzed dim...
An abiotic formation of <i>meso</i>- and dl-tartrates in 80% yield via the cyanide-catalyzed dimeriz...
A cycle remains a cycle only as long as the spokes of the wheel are not stolen. To keep the citric a...
Correction to “Merochlorins A–D, Cyclic Meroterpenoid Antibiotics Biosynthesized in Divergent Pathwa...
The citric acid cycle forms a major metabolic hub and as such it is involved in many disease states ...
Correction to “Palladium-Catalyzed Chemo- and Enantioselective Oxidation of Allylic Esters and Carbo...
<p>In the urea cycle: ammonia and bicarbonate form carbamoylphosphate via carbamoyl phosphate synthe...
Correction to “Manganese Catalyzed Dehydrogenative Synthesis of Urea Derivatives and Polyureas
Although cyanide’s biological effects are pleiotropic, its most obvious effects are as a metabolic p...
Correction to “Constructing Quaternary Stereogenic Centers Using Tertiary Organocuprates and Tertiar...
Correction to “Design, Development, Mechanistic Elucidation, and Rational Optimization of a Tandem I...
Significant metabolic changes occur in inflammation to respond to the new energetic needs of cells. ...
This article is a guided pedagogical approach, devoted to postgraduate students specializing in bio...
In 1937, Sir H. A Krebs first published the Citric Acid Cycle, a unidirectional cycle with carboxyli...
Correction to “Synthesis and Application of Substituted 1,16-Dihydroxytetraphenylenes in Catalytic A...
DOI
Add to ORKG