Diazoxide
Vue d'ensemble
Description
Le diazoxide est un dérivé de la benzothiadiazine non diurétique principalement utilisé pour gérer l'hypoglycémie due à l'hyperinsulinisme. Il est chimiquement apparenté aux diurétiques thiazidiques, mais n'inhibe pas l'anhydrase carbonique et n'a pas d'activité chloriurétique ou natriurétique . Le this compound est connu pour sa capacité à activer les canaux potassiques sensibles à l'ATP, ce qui contribue à inhiber la libération d'insuline .
Applications De Recherche Scientifique
Diazoxide has a wide range of scientific research applications:
Chemistry: Used in various synthetic pathways and as a reagent in multicomponent reactions.
Biology: Studied for its effects on cellular potassium channels and its role in modulating cellular activities.
Medicine: Primarily used to treat hyperinsulinemic hypoglycemia by inhibiting insulin release.
Industry: Utilized in the production of pharmaceuticals and as a research tool in drug development.
Mécanisme D'action
Target of Action
Diazoxide primarily targets the ATP-sensitive potassium channels, specifically the sulfonylurea receptor-1 subunit in the ATP-sensitive K+ (KATP) channel . These channels are present on the insulin-producing beta cells of the pancreas .
Mode of Action
This compound works by activating the ATP-sensitive potassium channels . This activation leads to the hyperpolarization of the cell membrane, which in turn decreases calcium influx and subsequently reduces the release of insulin . This mechanism of action is the mirror opposite of that of sulfonylureas, a class of medications used to increase insulin release in type 2 diabetics .
Biochemical Pathways
This compound’s action on the ATP-sensitive potassium channels leads to a series of downstream effects. The hyperpolarization of the cell membrane inhibits the secretion of insulin by the pancreas . This results in an increase in blood glucose levels . This compound also exhibits hypotensive activity and reduces arteriolar smooth muscle and vascular resistance .
Pharmacokinetics
This compound is readily and extensively absorbed. Peak blood concentrations are attained in 4 hours following oral administration . The drug is metabolized in the liver through oxidation and sulfate conjugation . The elimination half-life of this compound is between 21-45 hours, and it is excreted via the kidneys .
Result of Action
The primary result of this compound’s action is the inhibition of insulin release, leading to an increase in blood glucose levels . This makes this compound effective in the treatment of hyperinsulinaemic hypoglycemia . Additionally, this compound’s hypotensive activity can be used to treat hypertensive emergencies .
Action Environment
The efficacy and stability of this compound can be influenced by various environmental factors. For instance, the drug’s absorption, distribution, metabolism, and excretion can be affected by factors such as the patient’s age, liver function, and renal function . Furthermore, this compound’s effectiveness can be reduced in non-insulin dependent diabetic patients due to its mechanism of action .
Analyse Biochimique
Biochemical Properties
Diazoxide activates ATP-sensitive potassium channels . This activation leads to the hyperpolarization of cell membranes, which in turn inhibits the release of insulin . This biochemical property makes this compound particularly useful in the treatment of hyperinsulinemic hypoglycemia .
Cellular Effects
This compound has a significant impact on various types of cells and cellular processes. It influences cell function by inhibiting insulin release . This inhibition can affect cell signaling pathways, gene expression, and cellular metabolism . This compound also exhibits hypotensive activity and reduces arteriolar smooth muscle and vascular resistance .
Molecular Mechanism
This compound works by binding to the sulfonylurea receptor (SUR) subunit of the ATP-sensitive potassium channel (K ATP) channel on the membrane of pancreatic beta‐cells . This binding promotes a potassium efflux from beta-cells, leading to the inhibition of insulin release .
Temporal Effects in Laboratory Settings
The effects of this compound can change over time in laboratory settings. The plasma half-life of this compound varies from 9.5 to 24 hours in children with normal renal function and from 20 to 72 hours in adults with normal renal function . This indicates that the product’s stability and degradation, as well as any long-term effects on cellular function, need to be considered in both in vitro and in vivo studies .
Metabolic Pathways
This compound is metabolized in the liver through oxidation of the 3-methyl group, producing hydroxymethyl (MI) and carboxy (M2) derivatives . The MI derivatives undergo subsequent sulphate conjugation . It is estimated that, in subjects with normal renal function, 54-60% of this compound is metabolized .
Subcellular Localization
This compound is known to affect mitochondrial bioenergetics by opening the mKATP channel This suggests that this compound may be localized in the mitochondria of cells
Méthodes De Préparation
La préparation du diazoxide implique plusieurs voies de synthèse. Une méthode courante consiste à faire réagir l'o-aminobenzènesulfonamide avec le N-chlorosuccinimide dans un solvant chloré pour obtenir du 2-amino-5-chlorobenzènesulfonamide. Cet intermédiaire est ensuite mélangé à un sel d'imidazole et un solvant amide, puis chauffé pour obtenir du this compound . Cette méthode évite l'utilisation de réactifs hautement corrosifs et toxiques, ce qui la rend plus adaptée à la production industrielle .
Analyse Des Réactions Chimiques
Le diazoxide subit diverses réactions chimiques, notamment :
Oxydation : Le this compound peut être oxydé dans des conditions spécifiques, bien que les voies détaillées soient moins souvent discutées.
Réduction : Les réactions de réduction impliquant le this compound ne sont pas largement rapportées.
Substitution : Le this compound peut participer à des réactions de substitution, en particulier impliquant ses groupes fonctionnels. Les réactifs couramment utilisés dans ces réactions comprennent le N-chlorosuccinimide et les sels d'imidazole
4. Applications de la recherche scientifique
Le this compound a un large éventail d'applications de recherche scientifique :
Chimie : Utilisé dans diverses voies de synthèse et comme réactif dans des réactions multicomposants.
Biologie : Étudié pour ses effets sur les canaux potassiques cellulaires et son rôle dans la modulation des activités cellulaires.
Médecine : Principalement utilisé pour traiter l'hypoglycémie hyperinsulinémique en inhibant la libération d'insuline.
Industrie : Utilisé dans la production de produits pharmaceutiques et comme outil de recherche en développement de médicaments.
5. Mécanisme d'action
Le this compound agit en activant les canaux potassiques sensibles à l'ATP dans les cellules bêta du pancréas. Cette activation entraîne l'ouverture des canaux potassiques, provoquant une hyperpolarisation de la membrane cellulaire. En conséquence, il y a une diminution de l'afflux de calcium, ce qui inhibe la libération d'insuline . Ce mécanisme est l'opposé de celui des sulfonylurées, qui augmentent la libération d'insuline .
Comparaison Avec Des Composés Similaires
Le diazoxide est chimiquement similaire aux diurétiques thiazidiques, mais diffère par son absence d'activité diurétique. Les composés similaires comprennent :
Diurétiques thiazidiques : Comme l'hydrochlorothiazide, qui sont utilisés pour traiter l'hypertension et l'œdème, mais ont des mécanismes d'action différents.
Sulfonylurées : Comme le glibenclamide, qui augmentent la libération d'insuline et sont utilisés pour traiter le diabète de type 2. La capacité unique du this compound à inhiber la libération d'insuline tout en étant dépourvu d'activité diurétique le distingue de ces composés similaires.
Propriétés
IUPAC Name |
7-chloro-3-methyl-4H-1λ6,2,4-benzothiadiazine 1,1-dioxide | |
---|---|---|
Source | PubChem | |
URL | https://pubchem.ncbi.nlm.nih.gov | |
Description | Data deposited in or computed by PubChem | |
InChI |
InChI=1S/C8H7ClN2O2S/c1-5-10-7-3-2-6(9)4-8(7)14(12,13)11-5/h2-4H,1H3,(H,10,11) | |
Source | PubChem | |
URL | https://pubchem.ncbi.nlm.nih.gov | |
Description | Data deposited in or computed by PubChem | |
InChI Key |
GDLBFKVLRPITMI-UHFFFAOYSA-N | |
Source | PubChem | |
URL | https://pubchem.ncbi.nlm.nih.gov | |
Description | Data deposited in or computed by PubChem | |
Canonical SMILES |
CC1=NS(=O)(=O)C2=C(N1)C=CC(=C2)Cl | |
Source | PubChem | |
URL | https://pubchem.ncbi.nlm.nih.gov | |
Description | Data deposited in or computed by PubChem | |
Molecular Formula |
C8H7ClN2O2S | |
Source | PubChem | |
URL | https://pubchem.ncbi.nlm.nih.gov | |
Description | Data deposited in or computed by PubChem | |
DSSTOX Substance ID |
DTXSID7022914 | |
Record name | Diazoxide | |
Source | EPA DSSTox | |
URL | https://comptox.epa.gov/dashboard/DTXSID7022914 | |
Description | DSSTox provides a high quality public chemistry resource for supporting improved predictive toxicology. | |
Molecular Weight |
230.67 g/mol | |
Source | PubChem | |
URL | https://pubchem.ncbi.nlm.nih.gov | |
Description | Data deposited in or computed by PubChem | |
Physical Description |
Solid | |
Record name | Diazoxide | |
Source | Human Metabolome Database (HMDB) | |
URL | http://www.hmdb.ca/metabolites/HMDB0015251 | |
Description | The Human Metabolome Database (HMDB) is a freely available electronic database containing detailed information about small molecule metabolites found in the human body. | |
Explanation | HMDB is offered to the public as a freely available resource. Use and re-distribution of the data, in whole or in part, for commercial purposes requires explicit permission of the authors and explicit acknowledgment of the source material (HMDB) and the original publication (see the HMDB citing page). We ask that users who download significant portions of the database cite the HMDB paper in any resulting publications. | |
Solubility |
5.52e-01 g/L | |
Record name | Diazoxide | |
Source | DrugBank | |
URL | https://www.drugbank.ca/drugs/DB01119 | |
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Record name | Diazoxide | |
Source | Human Metabolome Database (HMDB) | |
URL | http://www.hmdb.ca/metabolites/HMDB0015251 | |
Description | The Human Metabolome Database (HMDB) is a freely available electronic database containing detailed information about small molecule metabolites found in the human body. | |
Explanation | HMDB is offered to the public as a freely available resource. Use and re-distribution of the data, in whole or in part, for commercial purposes requires explicit permission of the authors and explicit acknowledgment of the source material (HMDB) and the original publication (see the HMDB citing page). We ask that users who download significant portions of the database cite the HMDB paper in any resulting publications. | |
Mechanism of Action |
Diazoxide inhibits insulin release from the pancreas, by opening potassium channels in the beta cell membrane. Diazoxide is chemically related to thiazide diuretics but does not inhibit carbonic anhydrase and does not have chloriuretic or natriuretic activity. It also exhibits hypotensive activity by reducing arteriolar smooth muscle and vascular resistance. | |
Record name | Diazoxide | |
Source | DrugBank | |
URL | https://www.drugbank.ca/drugs/DB01119 | |
Description | The DrugBank database is a unique bioinformatics and cheminformatics resource that combines detailed drug (i.e. chemical, pharmacological and pharmaceutical) data with comprehensive drug target (i.e. sequence, structure, and pathway) information. | |
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CAS No. |
364-98-7 | |
Record name | Diazoxide | |
Source | CAS Common Chemistry | |
URL | https://commonchemistry.cas.org/detail?cas_rn=364-98-7 | |
Description | CAS Common Chemistry is an open community resource for accessing chemical information. Nearly 500,000 chemical substances from CAS REGISTRY cover areas of community interest, including common and frequently regulated chemicals, and those relevant to high school and undergraduate chemistry classes. This chemical information, curated by our expert scientists, is provided in alignment with our mission as a division of the American Chemical Society. | |
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Record name | Diazoxide [USAN:USP:INN:BAN:JAN] | |
Source | ChemIDplus | |
URL | https://pubchem.ncbi.nlm.nih.gov/substance/?source=chemidplus&sourceid=0000364987 | |
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Record name | Diazoxide | |
Source | DrugBank | |
URL | https://www.drugbank.ca/drugs/DB01119 | |
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Record name | diazoxide | |
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Record name | diazoxide | |
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Record name | diazoxide | |
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Record name | Diazoxide | |
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Record name | Diazoxide | |
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Record name | DIAZOXIDE | |
Source | FDA Global Substance Registration System (GSRS) | |
URL | https://gsrs.ncats.nih.gov/ginas/app/beta/substances/O5CB12L4FN | |
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Record name | Diazoxide | |
Source | Human Metabolome Database (HMDB) | |
URL | http://www.hmdb.ca/metabolites/HMDB0015251 | |
Description | The Human Metabolome Database (HMDB) is a freely available electronic database containing detailed information about small molecule metabolites found in the human body. | |
Explanation | HMDB is offered to the public as a freely available resource. Use and re-distribution of the data, in whole or in part, for commercial purposes requires explicit permission of the authors and explicit acknowledgment of the source material (HMDB) and the original publication (see the HMDB citing page). We ask that users who download significant portions of the database cite the HMDB paper in any resulting publications. | |
Melting Point |
330.5 °C | |
Record name | Diazoxide | |
Source | DrugBank | |
URL | https://www.drugbank.ca/drugs/DB01119 | |
Description | The DrugBank database is a unique bioinformatics and cheminformatics resource that combines detailed drug (i.e. chemical, pharmacological and pharmaceutical) data with comprehensive drug target (i.e. sequence, structure, and pathway) information. | |
Explanation | Creative Common's Attribution-NonCommercial 4.0 International License (http://creativecommons.org/licenses/by-nc/4.0/legalcode) | |
Record name | Diazoxide | |
Source | Human Metabolome Database (HMDB) | |
URL | http://www.hmdb.ca/metabolites/HMDB0015251 | |
Description | The Human Metabolome Database (HMDB) is a freely available electronic database containing detailed information about small molecule metabolites found in the human body. | |
Explanation | HMDB is offered to the public as a freely available resource. Use and re-distribution of the data, in whole or in part, for commercial purposes requires explicit permission of the authors and explicit acknowledgment of the source material (HMDB) and the original publication (see the HMDB citing page). We ask that users who download significant portions of the database cite the HMDB paper in any resulting publications. | |
Retrosynthesis Analysis
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Strategy Settings
Precursor scoring | Relevance Heuristic |
---|---|
Min. plausibility | 0.01 |
Model | Template_relevance |
Template Set | Pistachio/Bkms_metabolic/Pistachio_ringbreaker/Reaxys/Reaxys_biocatalysis |
Top-N result to add to graph | 6 |
Feasible Synthetic Routes
Q1: What is the primary target of diazoxide, and how does this interaction affect pancreatic β-cells?
A1: this compound primarily targets mitochondrial ATP-sensitive potassium (mitoKATP) channels [, , , ]. By binding to and opening these channels, this compound induces hyperpolarization of the β-cell membrane, effectively inhibiting insulin secretion [, , , , ]. This mechanism is thought to involve increased potassium permeability, ultimately reducing calcium influx and blocking insulin release [, , , ].
Q2: Beyond mitoKATP channels, does this compound interact with other targets to influence cellular processes?
A2: Research suggests that this compound might directly interact with mitochondrial F0F1 ATP synthase, promoting the binding of the inhibitor protein IF(1) and reversibly inhibiting ATP hydrolysis []. This interaction could contribute to the cardioprotective effects observed with this compound treatment [, , ].
Q3: this compound is known to influence calcium signaling in various cell types. How does this occur?
A3: this compound can modulate calcium signaling through multiple pathways. In rat ventricular myocytes, this compound has been shown to modulate the opening of the mitochondrial permeability transition pore, leading to an increase in calcium transients independently of changes in mitochondrial membrane potential []. In endothelial cells, this compound can increase intracellular calcium levels through both mitochondrial reactive oxygen species-dependent and -independent mechanisms, leading to activation of endothelial nitric oxide synthase (eNOS) and subsequent vasodilation [].
Q4: What is the molecular formula and weight of this compound?
A4: this compound has the molecular formula C8H7ClN2O3S and a molecular weight of 230.66 g/mol.
Q5: How do structural modifications of this compound impact its activity and selectivity for KATP channels?
A5: While the provided papers don't directly compare different this compound analogs, they highlight the importance of specific structural features. For instance, the presence of the sulfonylurea moiety is crucial for its interaction with KATP channels []. Further research exploring SAR could reveal modifications that enhance selectivity for mitoKATP channels over other subtypes.
Q6: What is the primary route of administration for this compound, and what is known about its pharmacokinetic profile?
A7: this compound can be administered intravenously or orally [, ]. It exhibits rapid but transient effects on plasma insulin and glucose levels, suggesting a short half-life []. One study observed that this compound crosses the placental barrier and is present in amniotic fluid and urine during fetal exposure [].
Q7: What are the documented effects of this compound on blood glucose and insulin levels in animal models?
A8: this compound consistently induces hyperglycemia in various animal models, including rats and mice [, ]. This effect is attributed to its inhibitory action on insulin secretion from pancreatic β-cells [, , ]. Notably, the magnitude of hyperglycemia can be modulated by calcium receptor activity [].
Q8: What is the clinical significance of this compound responsiveness in patients with congenital hyperinsulinism (CHI)?
A9: this compound responsiveness is a crucial factor in the management of CHI [, , ]. Patients with KATP-hyperinsulinism, particularly those with mutations in the ABCC8 or KCNJ11 genes, often exhibit this compound unresponsiveness []. This characteristic can guide treatment decisions, as this compound may be less effective in these cases, necessitating alternative therapies like octreotide or surgery [, ].
Q9: Have any adverse effects been reported in association with this compound treatment?
A10: While the provided papers don't extensively discuss adverse effects, some studies mention alopecia and hypertrichosis lanuginosa as potential side effects observed in infants exposed to this compound in utero []. Additionally, one study reports a case of this compound-induced neutropenia after prolonged treatment []. These findings highlight the importance of monitoring for potential side effects during this compound therapy.
Q10: Are there known mechanisms of resistance to this compound, particularly in the context of CHI?
A11: this compound unresponsiveness is a significant challenge in CHI management. Mutations in the ABCC8 and KCNJ11 genes, encoding subunits of the KATP channel, are strongly associated with this compound resistance [, ]. This suggests that these mutations disrupt the drug's ability to bind to and activate the channel, rendering it ineffective in suppressing insulin secretion.
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