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Appears in Networks 3

M1 muscarinic acetylcholine receptor in Alzheimer’s disease v1.0.0

This file encodes the article M1 muscarinic acetylcholine receptor in Alzheimer’s disease by Jiang et al, 2014

Heme Curation v0.0.1-dev

Mechanistic knowledge surrounding heme

In-Edges 2

p(HGNCGENEFAMILY:"Cholinergic receptors muscarinic") association a(MESH:Kidney) View Subject | View Object

Members of the mAChR family are widely expressed in various regions in the central nervous system (CNS) and in the peripheral system. They play crucial roles in diverse physiological processes such as memory, attention, nociception, motor control, sleep-wake cycles, and cardiovascular, renal, and gastrointestinal functions PubMed:24590577

p(HGNC:HBB) negativeCorrelation a(MESH:Kidney) View Subject | View Object

Old blood transfusion resulted in systemic free Hb total exposure (AUC0–∞) of 4600 μmol heme-h/l, which was primarily cleared by the kidney within 24 h. PubMed:26794659

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MeSH
Liver
Text Location
Results

Out-Edges 7

a(MESH:Kidney) association p(HGNCGENEFAMILY:"Cholinergic receptors muscarinic") View Subject | View Object

Members of the mAChR family are widely expressed in various regions in the central nervous system (CNS) and in the peripheral system. They play crucial roles in diverse physiological processes such as memory, attention, nociception, motor control, sleep-wake cycles, and cardiovascular, renal, and gastrointestinal functions PubMed:24590577

a(MESH:Kidney) increases deg(a(CHEBI:"amyloid-beta")) View Subject | View Object

Aβ in periphery is mainly cleared by blood components, such as red cells (RBCs) and monocytes, or some tissues and organs, such as the liver and kidney (Fig. 2) PubMed:29626319

a(MESH:Kidney) decreases a(CHEBI:"amyloid-beta") View Subject | View Object

By measuring Aβ levels in superior vena cava and inferior vena cava, it is clear thatAβ levels are getting lower and lower along the direction of the vein blood flow, and the contents of Aβ40 and total Aβ in artery are significantly less than those in vein, suggesting a part of Aβ40 and total Aβ can be cleared by peripheral organs and tissues, such as the liver, kidney, skin, and the gastrointestinal tract, although there is no change in Aβ42 concentrations (Xiang et al. 2015) PubMed:29626319

a(MESH:Kidney) decreases a(CHEBI:"amyloid-beta") View Subject | View Object

Among these peripheral organs and tissues mentioned above, the liver and kidney are considered to be the major organs for the clearance of Aβ in periphery (Ghiso et al. 2004) PubMed:29626319

a(MESH:Kidney) decreases a(CHEBI:"amyloid-beta polypeptide 40") View Subject | View Object

By measuring Aβ levels in superior vena cava and inferior vena cava, it is clear thatAβ levels are getting lower and lower along the direction of the vein blood flow, and the contents of Aβ40 and total Aβ in artery are significantly less than those in vein, suggesting a part of Aβ40 and total Aβ can be cleared by peripheral organs and tissues, such as the liver, kidney, skin, and the gastrointestinal tract, although there is no change in Aβ42 concentrations (Xiang et al. 2015) PubMed:29626319

a(MESH:Kidney) causesNoChange a(CHEBI:"amyloid-beta polypeptide 42") View Subject | View Object

By measuring Aβ levels in superior vena cava and inferior vena cava, it is clear thatAβ levels are getting lower and lower along the direction of the vein blood flow, and the contents of Aβ40 and total Aβ in artery are significantly less than those in vein, suggesting a part of Aβ40 and total Aβ can be cleared by peripheral organs and tissues, such as the liver, kidney, skin, and the gastrointestinal tract, although there is no change in Aβ42 concentrations (Xiang et al. 2015) PubMed:29626319

a(MESH:Kidney) negativeCorrelation p(HGNC:HBB) View Subject | View Object

Old blood transfusion resulted in systemic free Hb total exposure (AUC0–∞) of 4600 μmol heme-h/l, which was primarily cleared by the kidney within 24 h. PubMed:26794659

Appears in Networks:
Annotations
MeSH
Liver
Text Location
Results

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If you find BEL Commons useful in your work, please consider citing: Hoyt, C. T., Domingo-Fernández, D., & Hofmann-Apitius, M. (2018). BEL Commons: an environment for exploration and analysis of networks encoded in Biological Expression Language. Database, 2018(3), 1–11.