Exact Mass: 393.3031

Exact Mass Matches: 393.3031

Found 89 metabolites which its exact mass value is equals to given mass value 393.3031, within given mass tolerance error 0.05 dalton. Try search metabolite list with more accurate mass tolerance error 0.01 dalton.

undecylprodigiosin

(2Z,5Z)-3-methoxy-5-pyrrol-2-ylidene-2-[(5-undecyl-1H-pyrrol-2-yl)methylidene]pyrrole

C25H35N3O (393.278)


A member of the class of tripyrroles that is 1H-pyrrole substituted by (4-methoxy-1H,5H-[2,2-bipyrrol]-5-ylidene)methyl and undecyl groups at positions 2 and 5, respectively. It is a pigment produced by Stveptomyces coelicolor. D007155 - Immunologic Factors > D007166 - Immunosuppressive Agents D000890 - Anti-Infective Agents > D000900 - Anti-Bacterial Agents

   

P,P-Dioctyldiphenylamine

4-octyl-N-(4-octylphenyl)aniline

C28H43N (393.3395)


P,P-Dioctyldiphenylamine belongs to the class of organic compounds known as benzene and substituted derivatives. These are aromatic compounds containing one monocyclic ring system consisting of benzene.

   

(5E,8E,11E)-Hexadeca-5,8,11-trienoylcarnitine

3-(hexadeca-5,8,11-trienoyloxy)-4-(trimethylazaniumyl)butanoate

C23H39NO4 (393.2879)


(5E,8E,11E)-Hexadeca-5,8,11-trienoylcarnitine is an acylcarnitine. More specifically, it is an (5E,8E,11E)-hexadeca-5,8,11-trienoic acid ester of carnitine. Acylcarnitines were first discovered more than 70 year ago (PMID: 13825279). It is believed that there are more than 1000 types of acylcarnitines in the human body. The general role of acylcarnitines is to transport acyl-groups (organic acids and fatty acids) from the cytoplasm into the mitochondria so that they can be broken down to produce energy. This process is known as beta-oxidation. According to a recent review [Dambrova et al. 2021, Physiological Reviews], acylcarnitines (ACs) can be classified into 9 different categories depending on the type and size of their acyl-group: 1) short-chain ACs; 2) medium-chain ACs; 3) long-chain ACs; 4) very long-chain ACs; 5) hydroxy ACs; 6) branched chain ACs; 7) unsaturated ACs; 8) dicarboxylic ACs and 9) miscellaneous ACs. Short-chain ACs have acyl-groups with two to five carbons (C2-C5), medium-chain ACs have acyl-groups with six to thirteen carbons (C6-C13), long-chain ACs have acyl-groups with fourteen to twenty once carbons (C14-C21) and very long-chain ACs have acyl groups with more than 22 carbons. (5E,8E,11E)-Hexadeca-5,8,11-trienoylcarnitine is therefore classified as a long chain AC. As a long-chain acylcarnitine (5E,8E,11E)-Hexadeca-5,8,11-trienoylcarnitine is generally formed through esterification with long-chain fatty acids obtained from the diet. The main function of most long-chain acylcarnitines is to ensure long chain fatty acid transport into the mitochondria (PMID: 22804748). Altered levels of long-chain acylcarnitines can serve as useful markers for inherited disorders of long-chain fatty acid metabolism. Carnitine palmitoyltransferase I (CPT I, EC:2.3.1.21) is involved in the synthesis of long-chain acylcarnitines (more than C12) on the mitochondrial outer membrane. Elevated serum/plasma levels of long-chain acylcarnitines are not only markers for incomplete FA oxidation but also are indicators of altered carbohydrate and lipid metabolism. High serum concentrations of long-chain acylcarnitines in the postprandial or fed state are markers of insulin resistance and arise from insulins inability to inhibit CPT-1-dependent fatty acid metabolism in muscles and the heart (PMID: 19073774). Increased intracellular content of long-chain acylcarnitines is thought to serve as a feedback inhibition mechanism of insulin action (PMID: 23258903). In healthy subjects, increased concentrations of insulin effectively inhibits long-chain acylcarnitine production. Several studies have also found increased levels of circulating long-chain acylcarnitines in chronic heart failure patients (PMID: 26796394). The study of acylcarnitines is an active area of research and it is likely that many novel acylcarnitines will be discovered in the coming years. It is also likely that many novel roles in health and disease will be uncovered. An excellent review of the current state of knowledge for acylcarnitines is available at [Dambrova et al. 2021, Physiological Reviews].

   

Hexadeca-7,10,13-trienoylcarnitine

3-(hexadeca-7,10,13-trienoyloxy)-4-(trimethylazaniumyl)butanoate

C23H39NO4 (393.2879)


Hexadeca-7,10,13-trienoylcarnitine is an acylcarnitine. More specifically, it is an hexadeca-7,10,13-trienoic acid ester of carnitine. Acylcarnitines were first discovered more than 70 year ago (PMID: 13825279). It is believed that there are more than 1000 types of acylcarnitines in the human body. The general role of acylcarnitines is to transport acyl-groups (organic acids and fatty acids) from the cytoplasm into the mitochondria so that they can be broken down to produce energy. This process is known as beta-oxidation. According to a recent review [Dambrova et al. 2021, Physiological Reviews], acylcarnitines (ACs) can be classified into 9 different categories depending on the type and size of their acyl-group: 1) short-chain ACs; 2) medium-chain ACs; 3) long-chain ACs; 4) very long-chain ACs; 5) hydroxy ACs; 6) branched chain ACs; 7) unsaturated ACs; 8) dicarboxylic ACs and 9) miscellaneous ACs. Short-chain ACs have acyl-groups with two to five carbons (C2-C5), medium-chain ACs have acyl-groups with six to thirteen carbons (C6-C13), long-chain ACs have acyl-groups with fourteen to twenty once carbons (C14-C21) and very long-chain ACs have acyl groups with more than 22 carbons. Hexadeca-7,10,13-trienoylcarnitine is therefore classified as a long chain AC. As a long-chain acylcarnitine Hexadeca-7,10,13-trienoylcarnitine is generally formed through esterification with long-chain fatty acids obtained from the diet. The main function of most long-chain acylcarnitines is to ensure long chain fatty acid transport into the mitochondria (PMID: 22804748). Altered levels of long-chain acylcarnitines can serve as useful markers for inherited disorders of long-chain fatty acid metabolism. Carnitine palmitoyltransferase I (CPT I, EC:2.3.1.21) is involved in the synthesis of long-chain acylcarnitines (more than C12) on the mitochondrial outer membrane. Elevated serum/plasma levels of long-chain acylcarnitines are not only markers for incomplete FA oxidation but also are indicators of altered carbohydrate and lipid metabolism. High serum concentrations of long-chain acylcarnitines in the postprandial or fed state are markers of insulin resistance and arise from insulins inability to inhibit CPT-1-dependent fatty acid metabolism in muscles and the heart (PMID: 19073774). Increased intracellular content of long-chain acylcarnitines is thought to serve as a feedback inhibition mechanism of insulin action (PMID: 23258903). In healthy subjects, increased concentrations of insulin effectively inhibits long-chain acylcarnitine production. Several studies have also found increased levels of circulating long-chain acylcarnitines in chronic heart failure patients (PMID: 26796394). The study of acylcarnitines is an active area of research and it is likely that many novel acylcarnitines will be discovered in the coming years. It is also likely that many novel roles in health and disease will be uncovered. An excellent review of the current state of knowledge for acylcarnitines is available at [Dambrova et al. 2021, Physiological Reviews].

   

(6E,9E,12E)-Hexadeca-6,9,12-trienoylcarnitine

3-(hexadeca-6,9,12-trienoyloxy)-4-(trimethylazaniumyl)butanoate

C23H39NO4 (393.2879)


(6E,9E,12E)-Hexadeca-6,9,12-trienoylcarnitine is an acylcarnitine. More specifically, it is an (6E,9E,12E)-hexadeca-6,9,12-trienoic acid ester of carnitine. Acylcarnitines were first discovered more than 70 year ago (PMID: 13825279). It is believed that there are more than 1000 types of acylcarnitines in the human body. The general role of acylcarnitines is to transport acyl-groups (organic acids and fatty acids) from the cytoplasm into the mitochondria so that they can be broken down to produce energy. This process is known as beta-oxidation. According to a recent review [Dambrova et al. 2021, Physiological Reviews], acylcarnitines (ACs) can be classified into 9 different categories depending on the type and size of their acyl-group: 1) short-chain ACs; 2) medium-chain ACs; 3) long-chain ACs; 4) very long-chain ACs; 5) hydroxy ACs; 6) branched chain ACs; 7) unsaturated ACs; 8) dicarboxylic ACs and 9) miscellaneous ACs. Short-chain ACs have acyl-groups with two to five carbons (C2-C5), medium-chain ACs have acyl-groups with six to thirteen carbons (C6-C13), long-chain ACs have acyl-groups with fourteen to twenty once carbons (C14-C21) and very long-chain ACs have acyl groups with more than 22 carbons. (6E,9E,12E)-Hexadeca-6,9,12-trienoylcarnitine is therefore classified as a long chain AC. As a long-chain acylcarnitine (6E,9E,12E)-Hexadeca-6,9,12-trienoylcarnitine is generally formed through esterification with long-chain fatty acids obtained from the diet. The main function of most long-chain acylcarnitines is to ensure long chain fatty acid transport into the mitochondria (PMID: 22804748). Altered levels of long-chain acylcarnitines can serve as useful markers for inherited disorders of long-chain fatty acid metabolism. Carnitine palmitoyltransferase I (CPT I, EC:2.3.1.21) is involved in the synthesis of long-chain acylcarnitines (more than C12) on the mitochondrial outer membrane. Elevated serum/plasma levels of long-chain acylcarnitines are not only markers for incomplete FA oxidation but also are indicators of altered carbohydrate and lipid metabolism. High serum concentrations of long-chain acylcarnitines in the postprandial or fed state are markers of insulin resistance and arise from insulins inability to inhibit CPT-1-dependent fatty acid metabolism in muscles and the heart (PMID: 19073774). Increased intracellular content of long-chain acylcarnitines is thought to serve as a feedback inhibition mechanism of insulin action (PMID: 23258903). In healthy subjects, increased concentrations of insulin effectively inhibits long-chain acylcarnitine production. Several studies have also found increased levels of circulating long-chain acylcarnitines in chronic heart failure patients (PMID: 26796394). The study of acylcarnitines is an active area of research and it is likely that many novel acylcarnitines will be discovered in the coming years. It is also likely that many novel roles in health and disease will be uncovered. An excellent review of the current state of knowledge for acylcarnitines is available at [Dambrova et al. 2021, Physiological Reviews].

   

(4E,7E,10E)-Hexadeca-4,7,10-trienoylcarnitine

3-(hexadeca-4,7,10-trienoyloxy)-4-(trimethylazaniumyl)butanoate

C23H39NO4 (393.2879)


(4E,7E,10E)-Hexadeca-4,7,10-trienoylcarnitine is an acylcarnitine. More specifically, it is an (4E,7E,10E)-hexadeca-4,7,10-trienoic acid ester of carnitine. Acylcarnitines were first discovered more than 70 year ago (PMID: 13825279). It is believed that there are more than 1000 types of acylcarnitines in the human body. The general role of acylcarnitines is to transport acyl-groups (organic acids and fatty acids) from the cytoplasm into the mitochondria so that they can be broken down to produce energy. This process is known as beta-oxidation. According to a recent review [Dambrova et al. 2021, Physiological Reviews], acylcarnitines (ACs) can be classified into 9 different categories depending on the type and size of their acyl-group: 1) short-chain ACs; 2) medium-chain ACs; 3) long-chain ACs; 4) very long-chain ACs; 5) hydroxy ACs; 6) branched chain ACs; 7) unsaturated ACs; 8) dicarboxylic ACs and 9) miscellaneous ACs. Short-chain ACs have acyl-groups with two to five carbons (C2-C5), medium-chain ACs have acyl-groups with six to thirteen carbons (C6-C13), long-chain ACs have acyl-groups with fourteen to twenty once carbons (C14-C21) and very long-chain ACs have acyl groups with more than 22 carbons. (4E,7E,10E)-Hexadeca-4,7,10-trienoylcarnitine is therefore classified as a long chain AC. As a long-chain acylcarnitine (4E,7E,10E)-Hexadeca-4,7,10-trienoylcarnitine is generally formed through esterification with long-chain fatty acids obtained from the diet. The main function of most long-chain acylcarnitines is to ensure long chain fatty acid transport into the mitochondria (PMID: 22804748). Altered levels of long-chain acylcarnitines can serve as useful markers for inherited disorders of long-chain fatty acid metabolism. Carnitine palmitoyltransferase I (CPT I, EC:2.3.1.21) is involved in the synthesis of long-chain acylcarnitines (more than C12) on the mitochondrial outer membrane. Elevated serum/plasma levels of long-chain acylcarnitines are not only markers for incomplete FA oxidation but also are indicators of altered carbohydrate and lipid metabolism. High serum concentrations of long-chain acylcarnitines in the postprandial or fed state are markers of insulin resistance and arise from insulins inability to inhibit CPT-1-dependent fatty acid metabolism in muscles and the heart (PMID: 19073774). Increased intracellular content of long-chain acylcarnitines is thought to serve as a feedback inhibition mechanism of insulin action (PMID: 23258903). In healthy subjects, increased concentrations of insulin effectively inhibits long-chain acylcarnitine production. Several studies have also found increased levels of circulating long-chain acylcarnitines in chronic heart failure patients (PMID: 26796394). The study of acylcarnitines is an active area of research and it is likely that many novel acylcarnitines will be discovered in the coming years. It is also likely that many novel roles in health and disease will be uncovered. An excellent review of the current state of knowledge for acylcarnitines is available at [Dambrova et al. 2021, Physiological Reviews].

   

(7Z,11Z,14Z)-Hexadeca-7,11,14-trienoylcarnitine

3-(hexadeca-7,11,14-trienoyloxy)-4-(trimethylazaniumyl)butanoate

C23H39NO4 (393.2879)


(7Z,11Z,14Z)-Hexadeca-7,11,14-trienoylcarnitine is an acylcarnitine. More specifically, it is an (7Z,11Z,14Z)-hexadeca-7,11,14-trienoic acid ester of carnitine. Acylcarnitines were first discovered more than 70 year ago (PMID: 13825279). It is believed that there are more than 1000 types of acylcarnitines in the human body. The general role of acylcarnitines is to transport acyl-groups (organic acids and fatty acids) from the cytoplasm into the mitochondria so that they can be broken down to produce energy. This process is known as beta-oxidation. According to a recent review [Dambrova et al. 2021, Physiological Reviews], acylcarnitines (ACs) can be classified into 9 different categories depending on the type and size of their acyl-group: 1) short-chain ACs; 2) medium-chain ACs; 3) long-chain ACs; 4) very long-chain ACs; 5) hydroxy ACs; 6) branched chain ACs; 7) unsaturated ACs; 8) dicarboxylic ACs and 9) miscellaneous ACs. Short-chain ACs have acyl-groups with two to five carbons (C2-C5), medium-chain ACs have acyl-groups with six to thirteen carbons (C6-C13), long-chain ACs have acyl-groups with fourteen to twenty once carbons (C14-C21) and very long-chain ACs have acyl groups with more than 22 carbons. (7Z,11Z,14Z)-Hexadeca-7,11,14-trienoylcarnitine is therefore classified as a long chain AC. As a long-chain acylcarnitine (7Z,11Z,14Z)-Hexadeca-7,11,14-trienoylcarnitine is generally formed through esterification with long-chain fatty acids obtained from the diet. The main function of most long-chain acylcarnitines is to ensure long chain fatty acid transport into the mitochondria (PMID: 22804748). Altered levels of long-chain acylcarnitines can serve as useful markers for inherited disorders of long-chain fatty acid metabolism. Carnitine palmitoyltransferase I (CPT I, EC:2.3.1.21) is involved in the synthesis of long-chain acylcarnitines (more than C12) on the mitochondrial outer membrane. Elevated serum/plasma levels of long-chain acylcarnitines are not only markers for incomplete FA oxidation but also are indicators of altered carbohydrate and lipid metabolism. High serum concentrations of long-chain acylcarnitines in the postprandial or fed state are markers of insulin resistance and arise from insulins inability to inhibit CPT-1-dependent fatty acid metabolism in muscles and the heart (PMID: 19073774). Increased intracellular content of long-chain acylcarnitines is thought to serve as a feedback inhibition mechanism of insulin action (PMID: 23258903). In healthy subjects, increased concentrations of insulin effectively inhibits long-chain acylcarnitine production. Several studies have also found increased levels of circulating long-chain acylcarnitines in chronic heart failure patients (PMID: 26796394). The study of acylcarnitines is an active area of research and it is likely that many novel acylcarnitines will be discovered in the coming years. It is also likely that many novel roles in health and disease will be uncovered. An excellent review of the current state of knowledge for acylcarnitines is available at [Dambrova et al. 2021, Physiological Reviews].

   

(4E,7E,13E)-Hexadeca-4,7,13-trienoylcarnitine

3-(hexadeca-4,7,13-trienoyloxy)-4-(trimethylazaniumyl)butanoate

C23H39NO4 (393.2879)


(4E,7E,13E)-hexadeca-4,7,13-trienoylcarnitine is an acylcarnitine. More specifically, it is an (4E,7E,13E)-hexadeca-4,7,13-trienoic acid ester of carnitine. Acylcarnitines were first discovered more than 70 year ago (PMID: 13825279). It is believed that there are more than 1000 types of acylcarnitines in the human body. The general role of acylcarnitines is to transport acyl-groups (organic acids and fatty acids) from the cytoplasm into the mitochondria so that they can be broken down to produce energy. This process is known as beta-oxidation. According to a recent review [Dambrova et al. 2021, Physiological Reviews], acylcarnitines (ACs) can be classified into 9 different categories depending on the type and size of their acyl-group: 1) short-chain ACs; 2) medium-chain ACs; 3) long-chain ACs; 4) very long-chain ACs; 5) hydroxy ACs; 6) branched chain ACs; 7) unsaturated ACs; 8) dicarboxylic ACs and 9) miscellaneous ACs. Short-chain ACs have acyl-groups with two to five carbons (C2-C5), medium-chain ACs have acyl-groups with six to thirteen carbons (C6-C13), long-chain ACs have acyl-groups with fourteen to twenty once carbons (C14-C21) and very long-chain ACs have acyl groups with more than 22 carbons. (4E,7E,13E)-hexadeca-4,7,13-trienoylcarnitine is therefore classified as a long chain AC. As a long-chain acylcarnitine (4E,7E,13E)-hexadeca-4,7,13-trienoylcarnitine is generally formed through esterification with long-chain fatty acids obtained from the diet. The main function of most long-chain acylcarnitines is to ensure long chain fatty acid transport into the mitochondria (PMID: 22804748). Altered levels of long-chain acylcarnitines can serve as useful markers for inherited disorders of long-chain fatty acid metabolism. Carnitine palmitoyltransferase I (CPT I, EC:2.3.1.21) is involved in the synthesis of long-chain acylcarnitines (more than C12) on the mitochondrial outer membrane. Elevated serum/plasma levels of long-chain acylcarnitines are not only markers for incomplete FA oxidation but also are indicators of altered carbohydrate and lipid metabolism. High serum concentrations of long-chain acylcarnitines in the postprandial or fed state are markers of insulin resistance and arise from insulins inability to inhibit CPT-1-dependent fatty acid metabolism in muscles and the heart (PMID: 19073774). Increased intracellular content of long-chain acylcarnitines is thought to serve as a feedback inhibition mechanism of insulin action (PMID: 23258903). In healthy subjects, increased concentrations of insulin effectively inhibits long-chain acylcarnitine production. Several studies have also found increased levels of circulating long-chain acylcarnitines in chronic heart failure patients (PMID: 26796394). The study of acylcarnitines is an active area of research and it is likely that many novel acylcarnitines will be discovered in the coming years. It is also likely that many novel roles in health and disease will be uncovered. An excellent review of the current state of knowledge for acylcarnitines is available at [Dambrova et al. 2021, Physiological Reviews].

   

(6Z,10Z,14Z)-Hexadeca-6,10,14-trienoylcarnitine

3-(hexadeca-6,10,14-trienoyloxy)-4-(trimethylazaniumyl)butanoate

C23H39NO4 (393.2879)


(6Z,10Z,14Z)-Hexadeca-6,10,14-trienoylcarnitine is an acylcarnitine. More specifically, it is an (6Z,10Z,14Z)-hexadeca-6,10,14-trienoic acid ester of carnitine. Acylcarnitines were first discovered more than 70 year ago (PMID: 13825279). It is believed that there are more than 1000 types of acylcarnitines in the human body. The general role of acylcarnitines is to transport acyl-groups (organic acids and fatty acids) from the cytoplasm into the mitochondria so that they can be broken down to produce energy. This process is known as beta-oxidation. According to a recent review [Dambrova et al. 2021, Physiological Reviews], acylcarnitines (ACs) can be classified into 9 different categories depending on the type and size of their acyl-group: 1) short-chain ACs; 2) medium-chain ACs; 3) long-chain ACs; 4) very long-chain ACs; 5) hydroxy ACs; 6) branched chain ACs; 7) unsaturated ACs; 8) dicarboxylic ACs and 9) miscellaneous ACs. Short-chain ACs have acyl-groups with two to five carbons (C2-C5), medium-chain ACs have acyl-groups with six to thirteen carbons (C6-C13), long-chain ACs have acyl-groups with fourteen to twenty once carbons (C14-C21) and very long-chain ACs have acyl groups with more than 22 carbons. (6Z,10Z,14Z)-Hexadeca-6,10,14-trienoylcarnitine is therefore classified as a long chain AC. As a long-chain acylcarnitine (6Z,10Z,14Z)-Hexadeca-6,10,14-trienoylcarnitine is generally formed through esterification with long-chain fatty acids obtained from the diet. The main function of most long-chain acylcarnitines is to ensure long chain fatty acid transport into the mitochondria (PMID: 22804748). Altered levels of long-chain acylcarnitines can serve as useful markers for inherited disorders of long-chain fatty acid metabolism. Carnitine palmitoyltransferase I (CPT I, EC:2.3.1.21) is involved in the synthesis of long-chain acylcarnitines (more than C12) on the mitochondrial outer membrane. Elevated serum/plasma levels of long-chain acylcarnitines are not only markers for incomplete FA oxidation but also are indicators of altered carbohydrate and lipid metabolism. High serum concentrations of long-chain acylcarnitines in the postprandial or fed state are markers of insulin resistance and arise from insulins inability to inhibit CPT-1-dependent fatty acid metabolism in muscles and the heart (PMID: 19073774). Increased intracellular content of long-chain acylcarnitines is thought to serve as a feedback inhibition mechanism of insulin action (PMID: 23258903). In healthy subjects, increased concentrations of insulin effectively inhibits long-chain acylcarnitine production. Several studies have also found increased levels of circulating long-chain acylcarnitines in chronic heart failure patients (PMID: 26796394). The study of acylcarnitines is an active area of research and it is likely that many novel acylcarnitines will be discovered in the coming years. It is also likely that many novel roles in health and disease will be uncovered. An excellent review of the current state of knowledge for acylcarnitines is available at [Dambrova et al. 2021, Physiological Reviews].

   

N-Palmitoyl Histidine

2-[(1-Hydroxyhexadecylidene)amino]-3-(1H-imidazol-5-yl)propanoate

C22H39N3O3 (393.2991)


N-palmitoyl histidine belongs to the class of compounds known as N-acylamides. These are molecules characterized by a fatty acyl group linked to a primary amine by an amide bond. More specifically, it is a Palmitic acid amide of Histidine. It is believed that there are more than 800 types of N-acylamides in the human body. N-acylamides fall into several categories: amino acid conjugates (e.g., those acyl amides conjugated with amino acids), neurotransmitter conjugates (e.g., those acylamides conjugated with neurotransmitters), ethanolamine conjugates (e.g., those acylamides conjugated to ethanolamine), and taurine conjugates (e.g., those acyamides conjugated to taurine). N-Palmitoyl Histidine is an amino acid conjugate. N-acylamides can be classified into 9 different categories depending on the size of their acyl-group: 1) short-chain N-acylamides; 2) medium-chain N-acylamides; 3) long-chain N-acylamides; and 4) very long-chain N-acylamides; 5) hydroxy N-acylamides; 6) branched chain N-acylamides; 7) unsaturated N-acylamides; 8) dicarboxylic N-acylamides and 9) miscellaneous N-acylamides. N-Palmitoyl Histidine is therefore classified as a long chain N-acylamide. N-acyl amides have a variety of signaling functions in physiology, including in cardiovascular activity, metabolic homeostasis, memory, cognition, pain, motor control and others (PMID: 15655504). N-acyl amides have also been shown to play a role in cell migration, inflammation and certain pathological conditions such as diabetes, cancer, neurodegenerative disease, and obesity (PMID: 23144998; PMID: 25136293; PMID: 28854168).N-acyl amides can be synthesized both endogenously and by gut microbiota (PMID: 28854168). N-acylamides can be biosynthesized via different routes, depending on the parent amine group. N-acyl ethanolamines (NAEs) are formed via the hydrolysis of an unusual phospholipid precursor, N-acyl-phosphatidylethanolamine (NAPE), by a specific phospholipase D. N-acyl amino acids are synthesized via a circulating peptidase M20 domain containing 1 (PM20D1), which can catalyze the bidirectional the condensation and hydrolysis of a variety of N-acyl amino acids. The degradation of N-acylamides is largely mediated by an enzyme called fatty acid amide hydrolase (FAAH), which catalyzes the hydrolysis of N-acylamides into fatty acids and the biogenic amines. Many N-acylamides are involved in lipid signaling system through interactions with transient receptor potential channels (TRP). TRP channel proteins interact with N-acyl amides such as N-arachidonoyl ethanolamide (Anandamide), N-arachidonoyl dopamine and others in an opportunistic fashion (PMID: 23178153). This signaling system has been shown to play a role in the physiological processes involved in inflammation (PMID: 25136293). Other N-acyl amides, including N-oleoyl-glutamine, have also been characterized as TRP channel antagonists (PMID: 29967167). N-acylamides have also been shown to have G-protein-coupled receptors (GPCRs) binding activity (PMID: 28854168). The study of N-acylamides is an active area of research and it is likely that many novel N-acylamides will be discovered in the coming years. It is also likely that many novel roles in health and disease will be uncovered for these molecules.

   

N-Linoleoyl Isoleucine

2-[(1-Hydroxyoctadeca-9,12-dien-1-ylidene)amino]-3-methylpentanoate

C24H43NO3 (393.3243)


N-linoleoyl isoleucine belongs to the class of compounds known as N-acylamides. These are molecules characterized by a fatty acyl group linked to a primary amine by an amide bond. More specifically, it is a Linoleic acid amide of Isoleucine. It is believed that there are more than 800 types of N-acylamides in the human body. N-acylamides fall into several categories: amino acid conjugates (e.g., those acyl amides conjugated with amino acids), neurotransmitter conjugates (e.g., those acylamides conjugated with neurotransmitters), ethanolamine conjugates (e.g., those acylamides conjugated to ethanolamine), and taurine conjugates (e.g., those acyamides conjugated to taurine). N-Linoleoyl Isoleucine is an amino acid conjugate. N-acylamides can be classified into 9 different categories depending on the size of their acyl-group: 1) short-chain N-acylamides; 2) medium-chain N-acylamides; 3) long-chain N-acylamides; and 4) very long-chain N-acylamides; 5) hydroxy N-acylamides; 6) branched chain N-acylamides; 7) unsaturated N-acylamides; 8) dicarboxylic N-acylamides and 9) miscellaneous N-acylamides. N-Linoleoyl Isoleucine is therefore classified as a long chain N-acylamide. N-acyl amides have a variety of signaling functions in physiology, including in cardiovascular activity, metabolic homeostasis, memory, cognition, pain, motor control and others (PMID: 15655504). N-acyl amides have also been shown to play a role in cell migration, inflammation and certain pathological conditions such as diabetes, cancer, neurodegenerative disease, and obesity (PMID: 23144998; PMID: 25136293; PMID: 28854168).N-acyl amides can be synthesized both endogenously and by gut microbiota (PMID: 28854168). N-acylamides can be biosynthesized via different routes, depending on the parent amine group. N-acyl ethanolamines (NAEs) are formed via the hydrolysis of an unusual phospholipid precursor, N-acyl-phosphatidylethanolamine (NAPE), by a specific phospholipase D. N-acyl amino acids are synthesized via a circulating peptidase M20 domain containing 1 (PM20D1), which can catalyze the bidirectional the condensation and hydrolysis of a variety of N-acyl amino acids. The degradation of N-acylamides is largely mediated by an enzyme called fatty acid amide hydrolase (FAAH), which catalyzes the hydrolysis of N-acylamides into fatty acids and the biogenic amines. Many N-acylamides are involved in lipid signaling system through interactions with transient receptor potential channels (TRP). TRP channel proteins interact with N-acyl amides such as N-arachidonoyl ethanolamide (Anandamide), N-arachidonoyl dopamine and others in an opportunistic fashion (PMID: 23178153). This signaling system has been shown to play a role in the physiological processes involved in inflammation (PMID: 25136293). Other N-acyl amides, including N-oleoyl-glutamine, have also been characterized as TRP channel antagonists (PMID: 29967167). N-acylamides have also been shown to have G-protein-coupled receptors (GPCRs) binding activity (PMID: 28854168). The study of N-acylamides is an active area of research and it is likely that many novel N-acylamides will be discovered in the coming years. It is also likely that many novel roles in health and disease will be uncovered for these molecules.

   

N-Linoleoyl Leucine

2-[(1-Hydroxyoctadeca-9,12-dien-1-ylidene)amino]-4-methylpentanoate

C24H43NO3 (393.3243)


N-linoleoyl leucine belongs to the class of compounds known as N-acylamides. These are molecules characterized by a fatty acyl group linked to a primary amine by an amide bond. More specifically, it is a Linoleic acid amide of Leucine. It is believed that there are more than 800 types of N-acylamides in the human body. N-acylamides fall into several categories: amino acid conjugates (e.g., those acyl amides conjugated with amino acids), neurotransmitter conjugates (e.g., those acylamides conjugated with neurotransmitters), ethanolamine conjugates (e.g., those acylamides conjugated to ethanolamine), and taurine conjugates (e.g., those acyamides conjugated to taurine). N-Linoleoyl Leucine is an amino acid conjugate. N-acylamides can be classified into 9 different categories depending on the size of their acyl-group: 1) short-chain N-acylamides; 2) medium-chain N-acylamides; 3) long-chain N-acylamides; and 4) very long-chain N-acylamides; 5) hydroxy N-acylamides; 6) branched chain N-acylamides; 7) unsaturated N-acylamides; 8) dicarboxylic N-acylamides and 9) miscellaneous N-acylamides. N-Linoleoyl Leucine is therefore classified as a long chain N-acylamide. N-acyl amides have a variety of signaling functions in physiology, including in cardiovascular activity, metabolic homeostasis, memory, cognition, pain, motor control and others (PMID: 15655504). N-acyl amides have also been shown to play a role in cell migration, inflammation and certain pathological conditions such as diabetes, cancer, neurodegenerative disease, and obesity (PMID: 23144998; PMID: 25136293; PMID: 28854168).N-acyl amides can be synthesized both endogenously and by gut microbiota (PMID: 28854168). N-acylamides can be biosynthesized via different routes, depending on the parent amine group. N-acyl ethanolamines (NAEs) are formed via the hydrolysis of an unusual phospholipid precursor, N-acyl-phosphatidylethanolamine (NAPE), by a specific phospholipase D. N-acyl amino acids are synthesized via a circulating peptidase M20 domain containing 1 (PM20D1), which can catalyze the bidirectional the condensation and hydrolysis of a variety of N-acyl amino acids. The degradation of N-acylamides is largely mediated by an enzyme called fatty acid amide hydrolase (FAAH), which catalyzes the hydrolysis of N-acylamides into fatty acids and the biogenic amines. Many N-acylamides are involved in lipid signaling system through interactions with transient receptor potential channels (TRP). TRP channel proteins interact with N-acyl amides such as N-arachidonoyl ethanolamide (Anandamide), N-arachidonoyl dopamine and others in an opportunistic fashion (PMID: 23178153). This signaling system has been shown to play a role in the physiological processes involved in inflammation (PMID: 25136293). Other N-acyl amides, including N-oleoyl-glutamine, have also been characterized as TRP channel antagonists (PMID: 29967167). N-acylamides have also been shown to have G-protein-coupled receptors (GPCRs) binding activity (PMID: 28854168). The study of N-acylamides is an active area of research and it is likely that many novel N-acylamides will be discovered in the coming years. It is also likely that many novel roles in health and disease will be uncovered for these molecules.

   

2,2-Dimethyl-N-(2,4,6-trimethoxyphenyl)dodecanamide

2,2-Dimethyl-N-(2,4,6-trimethoxyphenyl)dodecanamide

C23H39NO4 (393.2879)


D004791 - Enzyme Inhibitors PD 128042 (CI 976) is a potent, orally active, and selective inhibitor of ACAT (acyl coenzyme A:cholesterol acyltransferase) with an IC50s of 73 nM. PD 128042 is also a potent LPAT (lysophospholipid acyltransferase) inhibitor. PD 128042 inhibits Golgi-associated LPAT activity (IC50=15 μM). PD 128042 inhibits multiple membrane trafficking steps, including ones found in the endocytic and secretory pathway[1][2][3].

   

undecylprodigiosin

3-methoxy-5-(1H-pyrrol-2-yl)-2-[(5-undecyl-1H-pyrrol-2-yl)methylidene]-2H-pyrrole

C25H35N3O (393.278)


   
   

(2E,4E,14E)-13-Hydroperoxy-N-(2-methylpropyl)icosa-2,4,14-trienamide

(2E,4E,14E)-13-Hydroperoxy-N-(2-methylpropyl)icosa-2,4,14-trienamide

C24H43NO3 (393.3243)


   

Norcassaidid|Norcassaidide

Norcassaidid|Norcassaidide

C23H39NO4 (393.2879)


   

(4RS,5RS,9SR,10RS,11Z)-4-methoxy-9-((dimethylamino)methyl)-12,15-epoxy-11(13)-en-decahydronaphthalen-16-ol

(4RS,5RS,9SR,10RS,11Z)-4-methoxy-9-((dimethylamino)methyl)-12,15-epoxy-11(13)-en-decahydronaphthalen-16-ol

C24H43NO3 (393.3243)


   

CCCCCCCC1=C(C)NC(C=C2C(=CC(=N2)C=2NC=CC=2)OC)=C1CCC

CCCCCCCC1=C(C)NC(C=C2C(=CC(=N2)C=2NC=CC=2)OC)=C1CCC

C25H35N3O (393.278)


   

MLS001077289-01!2-(2,2-DICYCLOHEXYLETHYL)PIPERIDINE 2-BUTENEDIOATE

"MLS001077289-01!2-(2,2-DICYCLOHEXYLETHYL)PIPERIDINE 2-BUTENEDIOATE"

C23H39NO4 (393.2879)


   

MLS000028601-01!2-[2,2-DICYCLOHEXYLETHYL]PIPERIDINE MALEATE SALT

"MLS000028601-01!2-[2,2-DICYCLOHEXYLETHYL]PIPERIDINE MALEATE SALT"

C23H39NO4 (393.2879)


   

(2E,4E,14E)-13-hydroperoxy-N-(2-methylpropyl)icosa-2,4,14-trienamide

NCGC00380659-01!(2E,4E,14E)-13-hydroperoxy-N-(2-methylpropyl)icosa-2,4,14-trienamide

C24H43NO3 (393.3243)


   

PGH2-EA

N-(9S,11R-epidioxy-15S-hydroxy-5Z,13E-prostadienoyl)-ethanolamine

C23H39NO4 (393.2879)


   

N-palmitoyl histidine

N-hexadecanoyl-histidine

C22H39N3O3 (393.2991)


   

CAR 16:3

3-[(4Z,7Z,10Z)-hexadecatrienoyloxy]-4-(trimethylazaniumyl)butanoate

C23H39NO4 (393.2879)


   

C19 Sphingosine-1-phosphate

Nonadecaphing-4-enine-1-phosphate

C19H40NO5P (393.2644)


   

2-(2H-Benzotriazol-2-yl)-6-dodecyl-4-methylphenol

2-(2H-Benzotriazol-2-yl)-6-dodecyl-4-methylphenol

C25H35N3O (393.278)


   

N,N,N,N,N-PENTAKIS(2-HYDROXYPROPYL)DIETHYLENETRIAMINE

N,N,N,N,N-PENTAKIS(2-HYDROXYPROPYL)DIETHYLENETRIAMINE

C19H43N3O5 (393.3203)


   

Bis(4-(2,4,4-trimethylpentan-2-yl)phenyl)amine

Bis(4-(2,4,4-trimethylpentan-2-yl)phenyl)amine

C28H43N (393.3395)


   

N,N-Bis(octylphenyl)amine

N,N-Bis(octylphenyl)amine

C28H43N (393.3395)


   

2-Dicyclohexylphosphino-2-(N,N-dimethylamino)biphenyl

2-Dicyclohexylphosphino-2-(N,N-dimethylamino)biphenyl

C26H36NP (393.2585)


   
   

Perhexiline maleate

Perhexiline maleate

C23H39NO4 (393.2879)


C78274 - Agent Affecting Cardiovascular System > C270 - Antihypertensive Agent > C333 - Calcium Channel Blocker C93038 - Cation Channel Blocker Perhexiline maleate is an orally active CPT1 and CPT2 inhibitor that reduces fatty acid metabolism. Perhexiline maleate induces mitochondrial dysfunction and apoptosis in hepatic cells. Perhexiline maleate can cross the blood brain barrier (BBB) and shows anti-tumor activity. Perhexiline maleate can be used in the research of cancers, and cardiovascular disease like angina[1][2][5].

   

p-hexyloxybenzylidene p-octylaniline

p-hexyloxybenzylidene p-octylaniline

C27H39NO (393.3031)


   

p-decyloxybenzylidene-p-butylaniline

p-decyloxybenzylidene-p-butylaniline

C27H39NO (393.3031)


   

Vanlube-81

4,4-Dioctyldiphenylamine

C28H43N (393.3395)


   
   

2-(Dicyclohexylphosphino)-N,N-dimethyl[1,1-biphenyl]-4-amine

2-(Dicyclohexylphosphino)-N,N-dimethyl[1,1-biphenyl]-4-amine

C26H36NP (393.2585)


   
   

8-[1,1,2,2,3,3,4,4-octadeuterio-4-(4-pyrimidin-2-ylpiperazin-1-yl)butyl]-8-azaspiro[4.5]decane-7,9-dione,hydrochloride

8-[1,1,2,2,3,3,4,4-octadeuterio-4-(4-pyrimidin-2-ylpiperazin-1-yl)butyl]-8-azaspiro[4.5]decane-7,9-dione,hydrochloride

C21H23D8N5O2 (393.298)


   

s-Geranylgeranyl-l-cysteine

s-Geranylgeranyl-l-cysteine

C23H39NO2S (393.2701)


An S-polyprenyl-L-cysteine where the polyprenyl moiety is specified as geranylgeranyl.

   

1-Hexadecanosulfonyl-O-L-Serine

1-Hexadecanosulfonyl-O-L-Serine

C19H39NO5S (393.2549)


   

N-Palmitoyl Histidine

2-[(1-Hydroxyhexadecylidene)amino]-3-(1H-imidazol-5-yl)propanoate

C22H39N3O3 (393.2991)


N-palmitoyl histidine belongs to the class of compounds known as N-acylamides. These are molecules characterized by a fatty acyl group linked to a primary amine by an amide bond. More specifically, it is a Palmitic acid amide of Histidine. It is believed that there are more than 800 types of N-acylamides in the human body. N-acylamides fall into several categories: amino acid conjugates (e.g., those acyl amides conjugated with amino acids), neurotransmitter conjugates (e.g., those acylamides conjugated with neurotransmitters), ethanolamine conjugates (e.g., those acylamides conjugated to ethanolamine), and taurine conjugates (e.g., those acyamides conjugated to taurine). N-Palmitoyl Histidine is an amino acid conjugate. N-acylamides can be classified into 9 different categories depending on the size of their acyl-group: 1) short-chain N-acylamides; 2) medium-chain N-acylamides; 3) long-chain N-acylamides; and 4) very long-chain N-acylamides; 5) hydroxy N-acylamides; 6) branched chain N-acylamides; 7) unsaturated N-acylamides; 8) dicarboxylic N-acylamides and 9) miscellaneous N-acylamides. N-Palmitoyl Histidine is therefore classified as a long chain N-acylamide. N-acyl amides have a variety of signaling functions in physiology, including in cardiovascular activity, metabolic homeostasis, memory, cognition, pain, motor control and others (PMID: 15655504). N-acyl amides have also been shown to play a role in cell migration, inflammation and certain pathological conditions such as diabetes, cancer, neurodegenerative disease, and obesity (PMID: 23144998; PMID: 25136293; PMID: 28854168).N-acyl amides can be synthesized both endogenously and by gut microbiota (PMID: 28854168). N-acylamides can be biosynthesized via different routes, depending on the parent amine group. N-acyl ethanolamines (NAEs) are formed via the hydrolysis of an unusual phospholipid precursor, N-acyl-phosphatidylethanolamine (NAPE), by a specific phospholipase D. N-acyl amino acids are synthesized via a circulating peptidase M20 domain containing 1 (PM20D1), which can catalyze the bidirectional the condensation and hydrolysis of a variety of N-acyl amino acids. The degradation of N-acylamides is largely mediated by an enzyme called fatty acid amide hydrolase (FAAH), which catalyzes the hydrolysis of N-acylamides into fatty acids and the biogenic amines. Many N-acylamides are involved in lipid signaling system through interactions with transient receptor potential channels (TRP). TRP channel proteins interact with N-acyl amides such as N-arachidonoyl ethanolamide (Anandamide), N-arachidonoyl dopamine and others in an opportunistic fashion (PMID: 23178153). This signaling system has been shown to play a role in the physiological processes involved in inflammation (PMID: 25136293). Other N-acyl amides, including N-oleoyl-glutamine, have also been characterized as TRP channel antagonists (PMID: 29967167). N-acylamides have also been shown to have G-protein-coupled receptors (GPCRs) binding activity (PMID: 28854168). The study of N-acylamides is an active area of research and it is likely that many novel N-acylamides will be discovered in the coming years. It is also likely that many novel roles in health and disease will be uncovered for these molecules.

   

(E,E,E)-geranylgeranylcysteine

(E,E,E)-geranylgeranylcysteine

C23H39NO2S (393.2701)


   

3-[(3R,7R,10S,12S,13R,17R)-3,7,12-trihydroxy-10,13-dimethyl-2,3,4,5,6,7,8,9,11,12,14,15,16,17-tetradecahydro-1H-cyclopenta[a]phenanthren-17-yl]butanoate

3-[(3R,7R,10S,12S,13R,17R)-3,7,12-trihydroxy-10,13-dimethyl-2,3,4,5,6,7,8,9,11,12,14,15,16,17-tetradecahydro-1H-cyclopenta[a]phenanthren-17-yl]butanoate

C23H37O5- (393.2641)


D005765 - Gastrointestinal Agents > D001647 - Bile Acids and Salts D005765 - Gastrointestinal Agents > D002793 - Cholic Acids

   

4-methyl-2-[[(9E,12E)-octadeca-9,12-dienoyl]amino]pentanoic acid

4-methyl-2-[[(9E,12E)-octadeca-9,12-dienoyl]amino]pentanoic acid

C24H43NO3 (393.3243)


   

N-Linoleoyl Isoleucine

N-Linoleoyl Isoleucine

C24H43NO3 (393.3243)


   

Hexadeca-7,10,13-trienoylcarnitine

Hexadeca-7,10,13-trienoylcarnitine

C23H39NO4 (393.2879)


   

(5E,8E,11E)-Hexadeca-5,8,11-trienoylcarnitine

(5E,8E,11E)-Hexadeca-5,8,11-trienoylcarnitine

C23H39NO4 (393.2879)


   

(6E,9E,12E)-Hexadeca-6,9,12-trienoylcarnitine

(6E,9E,12E)-Hexadeca-6,9,12-trienoylcarnitine

C23H39NO4 (393.2879)


   

(4E,7E,10E)-Hexadeca-4,7,10-trienoylcarnitine

(4E,7E,10E)-Hexadeca-4,7,10-trienoylcarnitine

C23H39NO4 (393.2879)


   

(4E,7E,13E)-Hexadeca-4,7,13-trienoylcarnitine

(4E,7E,13E)-Hexadeca-4,7,13-trienoylcarnitine

C23H39NO4 (393.2879)


   

(7Z,11Z,14Z)-Hexadeca-7,11,14-trienoylcarnitine

(7Z,11Z,14Z)-Hexadeca-7,11,14-trienoylcarnitine

C23H39NO4 (393.2879)


   

(6Z,10Z,14Z)-Hexadeca-6,10,14-trienoylcarnitine

(6Z,10Z,14Z)-Hexadeca-6,10,14-trienoylcarnitine

C23H39NO4 (393.2879)


   

(8S,9S)-9-[[cyclopropylmethyl(methyl)amino]methyl]-6-[(2R)-1-hydroxypropan-2-yl]-8-methyl-10-oxa-1,6,14,15-tetrazabicyclo[10.3.0]pentadeca-12,14-dien-5-one

(8S,9S)-9-[[cyclopropylmethyl(methyl)amino]methyl]-6-[(2R)-1-hydroxypropan-2-yl]-8-methyl-10-oxa-1,6,14,15-tetrazabicyclo[10.3.0]pentadeca-12,14-dien-5-one

C20H35N5O3 (393.274)


   

Arterolane cation

Arterolane cation

C22H37N2O4+ (393.2753)


   

N-[(4E,8E,12E)-1,3-dihydroxyhexadeca-4,8,12-trien-2-yl]octanamide

N-[(4E,8E,12E)-1,3-dihydroxyhexadeca-4,8,12-trien-2-yl]octanamide

C24H43NO3 (393.3243)


   

N-[(4E,8E,12E)-1,3-dihydroxydocosa-4,8,12-trien-2-yl]acetamide

N-[(4E,8E,12E)-1,3-dihydroxydocosa-4,8,12-trien-2-yl]acetamide

C24H43NO3 (393.3243)


   

N-[(4E,8E,12E)-1,3-dihydroxyicosa-4,8,12-trien-2-yl]butanamide

N-[(4E,8E,12E)-1,3-dihydroxyicosa-4,8,12-trien-2-yl]butanamide

C24H43NO3 (393.3243)


   

N-[(4E,8E,12E)-1,3-dihydroxyoctadeca-4,8,12-trien-2-yl]hexanamide

N-[(4E,8E,12E)-1,3-dihydroxyoctadeca-4,8,12-trien-2-yl]hexanamide

C24H43NO3 (393.3243)


   

N-[(4E,8E,12E)-1,3-dihydroxypentadeca-4,8,12-trien-2-yl]nonanamide

N-[(4E,8E,12E)-1,3-dihydroxypentadeca-4,8,12-trien-2-yl]nonanamide

C24H43NO3 (393.3243)


   

(9Z,12Z)-N-[(E)-1,3-dihydroxyoct-4-en-2-yl]hexadeca-9,12-dienamide

(9Z,12Z)-N-[(E)-1,3-dihydroxyoct-4-en-2-yl]hexadeca-9,12-dienamide

C24H43NO3 (393.3243)


   

N-[(4E,8E,12E)-1,3-dihydroxyhenicosa-4,8,12-trien-2-yl]propanamide

N-[(4E,8E,12E)-1,3-dihydroxyhenicosa-4,8,12-trien-2-yl]propanamide

C24H43NO3 (393.3243)


   

N-[(4E,8E,12E)-1,3-dihydroxyheptadeca-4,8,12-trien-2-yl]heptanamide

N-[(4E,8E,12E)-1,3-dihydroxyheptadeca-4,8,12-trien-2-yl]heptanamide

C24H43NO3 (393.3243)


   

(7Z,10Z,13Z)-N-(1,3-dihydroxyoctan-2-yl)hexadeca-7,10,13-trienamide

(7Z,10Z,13Z)-N-(1,3-dihydroxyoctan-2-yl)hexadeca-7,10,13-trienamide

C24H43NO3 (393.3243)


   

N-[(4E,8E,12E)-1,3-dihydroxynonadeca-4,8,12-trien-2-yl]pentanamide

N-[(4E,8E,12E)-1,3-dihydroxynonadeca-4,8,12-trien-2-yl]pentanamide

C24H43NO3 (393.3243)


   

N-[(4E,8E,12E)-1,3-dihydroxytetradeca-4,8,12-trien-2-yl]decanamide

N-[(4E,8E,12E)-1,3-dihydroxytetradeca-4,8,12-trien-2-yl]decanamide

C24H43NO3 (393.3243)


   

PD 128042

2,2-Dimethyl-N-(2,4,6-trimethoxyphenyl)dodecanamide

C23H39NO4 (393.2879)


D004791 - Enzyme Inhibitors PD 128042 (CI 976) is a potent, orally active, and selective inhibitor of ACAT (acyl coenzyme A:cholesterol acyltransferase) with an IC50s of 73 nM. PD 128042 is also a potent LPAT (lysophospholipid acyltransferase) inhibitor. PD 128042 inhibits Golgi-associated LPAT activity (IC50=15 μM). PD 128042 inhibits multiple membrane trafficking steps, including ones found in the endocytic and secretory pathway[1][2][3].

   

N-hexadecanoyl-histidine

N-hexadecanoyl-histidine

C22H39N3O3 (393.2991)


   

Nonadecaphing-4-enine-1-phosphate

Nonadecaphing-4-enine-1-phosphate

C19H40NO5P (393.2644)


   

NA-Gly 22:2(13Z,16Z)

NA-Gly 22:2(13Z,16Z)

C24H43NO3 (393.3243)


   
   

NA-Ile 18:2(9E,12E)

NA-Ile 18:2(9E,12E)

C24H43NO3 (393.3243)


   

NA-Ile 18:2(9Z,12Z)

NA-Ile 18:2(9Z,12Z)

C24H43NO3 (393.3243)


   

NA-Leu 18:2(9E,12E)

NA-Leu 18:2(9E,12E)

C24H43NO3 (393.3243)


   

NA-Leu 18:2(9Z,12Z)

NA-Leu 18:2(9Z,12Z)

C24H43NO3 (393.3243)


   

NA-Ser 20:3(8Z,11Z,14Z)

NA-Ser 20:3(8Z,11Z,14Z)

C23H39NO4 (393.2879)


   

C19 Sphingosine 1-phosphate

C19 Sphingosine 1-phosphate

C19H40NO5P (393.2644)


   

ST 21:0;O2;Gly

ST 21:0;O2;Gly

C23H39NO4 (393.2879)


   

2-[(1r,2e,4ar,4br,7s,8ar,10s,10as)-7,10-dihydroxy-1,4b,8,8-tetramethyl-decahydro-1h-phenanthren-2-ylidene]-n-(2-hydroxyethyl)-n-methylacetamide

2-[(1r,2e,4ar,4br,7s,8ar,10s,10as)-7,10-dihydroxy-1,4b,8,8-tetramethyl-decahydro-1h-phenanthren-2-ylidene]-n-(2-hydroxyethyl)-n-methylacetamide

C23H39NO4 (393.2879)


   

4-methoxy-5-{[(2e)-5-undecylpyrrol-2-ylidene]methyl}-1h,1'h-2,2'-bipyrrole

4-methoxy-5-{[(2e)-5-undecylpyrrol-2-ylidene]methyl}-1h,1'h-2,2'-bipyrrole

C25H35N3O (393.278)


   

(e,5e)-4-methoxy-5-[(5-undecyl-1h-pyrrol-2-yl)methylidene]-1h-2,2'-bipyrrolylidene

(e,5e)-4-methoxy-5-[(5-undecyl-1h-pyrrol-2-yl)methylidene]-1h-2,2'-bipyrrolylidene

C25H35N3O (393.278)


   

(5z)-4-methoxy-5-[(5-undecyl-1h-pyrrol-2-yl)methylidene]-1'h-2,2'-bipyrrole

(5z)-4-methoxy-5-[(5-undecyl-1h-pyrrol-2-yl)methylidene]-1'h-2,2'-bipyrrole

C25H35N3O (393.278)


   

4-methoxy-5-[(5-undecyl-1h-pyrrol-2-yl)methylidene]-1'h-2,2'-bipyrrole

4-methoxy-5-[(5-undecyl-1h-pyrrol-2-yl)methylidene]-1'h-2,2'-bipyrrole

C25H35N3O (393.278)


   

2-(7,10-dihydroxy-1,4b,8,8-tetramethyl-decahydro-1h-phenanthren-2-ylidene)-n-(2-hydroxyethyl)-n-methylacetamide

2-(7,10-dihydroxy-1,4b,8,8-tetramethyl-decahydro-1h-phenanthren-2-ylidene)-n-(2-hydroxyethyl)-n-methylacetamide

C23H39NO4 (393.2879)


   

5-[(4-heptyl-5-methyl-3-propyl-1h-pyrrol-2-yl)methylidene]-4-methoxy-1'h-2,2'-bipyrrole

5-[(4-heptyl-5-methyl-3-propyl-1h-pyrrol-2-yl)methylidene]-4-methoxy-1'h-2,2'-bipyrrole

C25H35N3O (393.278)


   

(5e)-5-[(4-heptyl-5-methyl-3-propyl-1h-pyrrol-2-yl)methylidene]-4-methoxy-1'h-2,2'-bipyrrole

(5e)-5-[(4-heptyl-5-methyl-3-propyl-1h-pyrrol-2-yl)methylidene]-4-methoxy-1'h-2,2'-bipyrrole

C25H35N3O (393.278)


   

undecylprodigiosin red pigment

undecylprodigiosin red pigment

C25H35N3O (393.278)