Louis H. Philipson mainly investigates Internal medicine, Endocrinology, Molecular biology, Insulin and Cell biology. His studies deal with areas such as Diabetes mellitus and Intracellular as well as Internal medicine. In his study, which falls under the umbrella issue of Endocrinology, Tetraethylammonium, Membrane potential and NAD+ kinase is strongly linked to Patch clamp.
Louis H. Philipson combines subjects such as Nucleic acid sequence, Cellular differentiation, Peptide sequence, Messenger RNA and Cell cycle with his study of Molecular biology. His Insulin research integrates issues from Mutation, Glycolysis, Depolarization and Mitochondrion. His Cell biology study incorporates themes from Protein subunit, Gene expression, Neurotransmission and Knockout mouse.
Internal medicine, Endocrinology, Diabetes mellitus, Insulin and Molecular biology are his primary areas of study. His Internal medicine study frequently draws connections between adjacent fields such as Intracellular. His Endocrinology study frequently links to other fields, such as Cell biology.
His Diabetes mellitus research incorporates elements of Pediatrics and Genetic testing. The study incorporates disciplines such as Mutation, Exocytosis and Permanent neonatal diabetes mellitus in addition to Insulin. His Molecular biology research focuses on Gene expression and how it relates to Transcription.
Louis H. Philipson mostly deals with Diabetes mellitus, Insulin, Internal medicine, Pediatrics and Type 1 diabetes. Louis H. Philipson has included themes like Young adult, Proband and MEDLINE in his Diabetes mellitus study. The various areas that Louis H. Philipson examines in his Insulin study include HNF1A, Beta and Confidence interval.
His Internal medicine research is multidisciplinary, incorporating elements of Gastroenterology and Endocrinology. Louis H. Philipson has researched Endocrinology in several fields, including Hemoglobin and Permanent neonatal diabetes mellitus. His study focuses on the intersection of Cell and fields such as Gene with connections in the field of Cell biology.
Louis H. Philipson mainly focuses on Diabetes mellitus, Insulin, Internal medicine, Endocrinology and Type 1 diabetes. His work carried out in the field of Diabetes mellitus brings together such families of science as Pregnancy, Proband, Immunology, Autoimmunity and Pediatrics. His biological study spans a wide range of topics, including Receptor and Signal transduction.
His work in the fields of Internal medicine, such as Islet, overlaps with other areas such as Edmonton protocol. His research in Insulin resistance, Pancreas, Hypoglycemia and Glucagon secretion are components of Endocrinology. His work is dedicated to discovering how Type 1 diabetes, Cell are connected with Insulitis, Gene, HNF1A, Cell biology and Transcription factor and other disciplines.
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Disruption of the clock components CLOCK and BMAL1 leads to hypoinsulinaemia and diabetes
Biliana Marcheva;Kathryn Moynihan Ramsey;Ethan D. Buhr;Yumiko Kobayashi.
Polyadenylic Acid Sequences: Role in Conversion of Nuclear RNA into Messenger RNA
J. E. Darnell;L. Philipson;R. Wall;M. Adesnik.
Complete sequence of the staphylococcal gene encoding protein A. A gene evolved through multiple duplications.
M Uhlén;B Guss;B Nilsson;S Gatenbeck.
Journal of Biological Chemistry (1984)
Insulin gene mutations as a cause of permanent neonatal diabetes
Julie Støy;Emma L. Edghill;Sarah E. Flanagan;Honggang Ye.
Proceedings of the National Academy of Sciences of the United States of America (2007)
Insulin Mutation Screening in 1,044 Patients With Diabetes: Mutations in the INS Gene Are a Common Cause of Neonatal Diabetes but a Rare Cause of Diabetes Diagnosed in Childhood or Adulthood
Emma L. Edghill;Sarah E. Flanagan;Ann-Marie Patch;Chris Boustred.
CHOP (GADD153) and its oncogenic variant, TLS-CHOP, have opposing effects on the induction of G1/S arrest.
M V Barone;A Crozat;A Tabaee;L Philipson.
Genes & Development (1994)
Conditional gene targeting in mouse pancreatic β-cells: Analysis of ectopic Cre transgene expression in the brain
Barton Wicksteed;Marcela Brissova;Wenbo Yan;Darren M. Opland.
Addition of Polyadenylate Sequences to Virus-Specific RNA during Adenovirus Replication
L. Philipson;R. Wall;G. Glickman;J. E. Darnell.
Proceedings of the National Academy of Sciences of the United States of America (1971)
Structure and functional characterization of neuronal alpha 1E calcium channel subtypes.
Mark E. Williams;Lisa M. Marubio;Charles R. Deal;Michael Hans.
Journal of Biological Chemistry (1994)
Intracellular transport of insulin granules is a subordinated random walk
S. M. Ali Tabei;Stanislav Burov;Hee Y. Kim;Andrey Kuznetsov.
Proceedings of the National Academy of Sciences of the United States of America (2013)
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