Results 211 to 220 of about 12,810 (265)

Cholinesterases and Cholinesterase Inhibitors

Archives of Neurology, 2001
1. Introduction 2. Cholinesterase Inhibitors: An Introduction 3. Molecular Structure of Cholinesterases and Complexes with Inhibitors 4. Rational Design of Cholinesterase Inhibitors 5. Genetics and Epigenetics of Mammalian Cholinesterases 6. The Gene Structure of Cholinesterases 7. Molecular Forms and Anchoring of Cholinesterases 8. Mechanism of Action
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The Cholinesterase Inhibitors

Journal of Psychiatric Practice, 2003
Dementia is a serious and growing problem that presents enormous burdens to patients, their families, and national healthcare systems throughout the world. In the United States, there are currently two classes of psychopharmacologic agents approved for the treatment of Alzheimer's disease: the cholinesterase inhibitors, which are approved for use in ...
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Cholinesterase in a Receptor

Science, 1958
Cholinesterase is found at the sites for mechanoelectric conversion of Pacinian corpuscles; its acetylcholine-splitting activity is of the same order of magnitude as that of the cholinesterase at neuromuscular junctions. The enzyme is not a typical acetylcholinesterase.
W R, Loewenstein, D, Molins
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Cholinesterase of Leucocytes

American Journal of Physiology-Legacy Content, 1955
By using the Michel's method specific cholinesterase was found in the leucocytes of man, dog and rabbit. The largest quantities were found in the leucocytes of rabbit, followed by that of man and lastly by that found in the dog. The pus cells do not contain cholinesterase.
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Cholinesterase and anaesthesia

Clinical Biochemistry, 1979
Summary There appear to be two genetic loci for cholinesterase, E 1 and E 2 . The first allele is closely linked with the transferrin locus and is probably on chromosome number 1. At the second (E 2 ) locus only one variant has been described. At the E 1 locus at least 4 alleles have been detected: the usual (E 1 u ), atypical (E 1 a ), fluoride ...
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THE POLYMORPHISM OF CHOLINESTERASE IN VERTEBRATES

Neurochemistry International, 1980
Acetylcholinesterase (AChE, E.C. 3.1.1.7.) and butyrylcholinesterase (BuChE, E.C. 3.1.1.8.) form homologous sets of multiple molecular forms, the structure of which is well conserved among vertebrates. Two classes of molecular forms may be distinguished. The asymmetric forms contain one, two or three catalytic tetramers, associated with a collagen-like
J, Massoulié, S, Bon, M, Vigny
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Cholinesterase Nevus: Cholinesterases in Pigmented Tumors of the Skin

Archives of Dermatology, 1960
One of the enigmas of modern cytology is the nevus cell. Its origin has been variously claimed to be from melanocytes, 1 from epidermal cells, 2 and from nerve cells, 3 and each source has been hotly debated. It has been thought to grow up into the skin 4 and also to form by "abtropfung" 5 from the epidermis down into the dermis.
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Benzamides and cholinesterases.

Research communications in chemical pathology and pharmacology, 1987
At certain doses metoclopramide (MT), sulpiride and bromopride produce anti-cholinesterase effects as shown by studies on the serum and erythrocyte cholinesterases of the rabbit and the dog, and by those on the hypotensive effect of ACh incubated with rabbit serum in the presence or absence of MT. The anti-cholinesterase effect of MT was more intensive
VACCA C, MAIONE, Sabatino, TOZZI A, MARMO E.   +3 more
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Cholinesterase

Science, 1944
B, Mendel, H, Rudney
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Cholinesterases

Science, 1944
G A, Alles, R C, Hawes
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