Project description:Despite advances in surgery and radiotherapy, glioblastoma (GBM) remains the deadliest adult brain cancer with unacceptable low median survival rates. Targeted therapies and biologics have failed to improve outcome and the standard-of-care against GBM has not changed in two decades. GBM, like many solid tumors are thought to be organized hierarchically with a small number of radiation- and chemotherapy-resistant glioma stem cells (GSCs) producing more differentiated progeny and can repopulate tumors after sublethal treatment.In this study we sought to develop novel compounds that cross the blood-brain barrier (BBB), target existing GSCs and interfere with glioma cell plasticity to prevent the induction of GSCs in response to irradiation. We show that novel urea compounds target existing GSCs, prevent the radiation-induced conversion of non-stem glioma cells into GSCs and prolong the median survival in mouse models of GBM with minimal normal tissue toxicity.

Project description:Despite advances in surgery and radiotherapy, glioblastoma (GBM) remains the deadliest adult brain cancer with unacceptable low median survival rates. Targeted therapies and biologics have failed to improve outcome and the standard-of-care against GBM has not changed in two decades. GBM, like many solid tumors are thought to be organized hierarchically with a small number of radiation- and chemotherapy-resistant glioma stem cells (GSCs) producing more differentiated progeny and can repopulate tumors after sublethal treatment.In this study we sought to develop novel compounds that cross the blood-brain barrier (BBB), target existing GSCs and interfere with glioma cell plasticity to prevent the induction of GSCs in response to irradiation. We show that novel urea compounds target existing GSCs, prevent the radiation-induced conversion of non-stem glioma cells into GSCs and prolong the median survival in mouse models of GBM with minimal normal tissue toxicity.

Project description:Despite advances in surgery and radiotherapy, glioblastoma (GBM) remains the deadliest adult brain cancer with unacceptable low median survival rates. Targeted therapies and biologics have failed to improve outcome and the standard-of-care against GBM has not changed in two decades. GBM, like many solid tumors are thought to be organized hierarchically with a small number of radiation- and chemotherapy-resistant glioma stem cells (GSCs) producing more differentiated progeny and can repopulate tumors after sublethal treatment.In this study we sought to develop novel compounds that cross the blood-brain barrier (BBB), target existing GSCs and interfere with glioma cell plasticity to prevent the induction of GSCs in response to irradiation. We show that novel urea compounds target existing GSCs, prevent the radiation-induced conversion of non-stem glioma cells into GSCs and prolong the median survival in mouse models of GBM with minimal normal tissue toxicity.

Project description:Despite advances in surgery and radiotherapy, glioblastoma (GBM) remains the deadliest adult brain cancer with unacceptable low median survival rates. Targeted therapies and biologics have failed to improve outcome and the standard-of-care against GBM has not changed in two decades. GBM, like many solid tumors are thought to be organized hierarchically with a small number of radiation- and chemotherapy-resistant glioma stem cells (GSCs) producing more differentiated progeny and can repopulate tumors after sublethal treatment.In this study we sought to develop novel compounds that cross the blood-brain barrier (BBB), target existing GSCs and interfere with glioma cell plasticity to prevent the induction of GSCs in response to irradiation. We show that novel urea compounds target existing GSCs, prevent the radiation-induced conversion of non-stem glioma cells into GSCs and prolong the median survival in mouse models of GBM with minimal normal tissue toxicity.

Project description:Despite advances in surgery and radiotherapy, glioblastoma (GBM) remains the deadliest adult brain cancer with unacceptable low median survival rates. Targeted therapies and biologics have failed to improve outcome and the standard-of-care against GBM has not changed in two decades. GBM, like many solid tumors are thought to be organized hierarchically with a small number of radiation- and chemotherapy-resistant glioma stem cells (GSCs) producing more differentiated progeny and can repopulate tumors after sublethal treatment.In this study we sought to develop novel compounds that cross the blood-brain barrier (BBB), target existing GSCs and interfere with glioma cell plasticity to prevent the induction of GSCs in response to irradiation. We show that novel urea compounds target existing GSCs, prevent the radiation-induced conversion of non-stem glioma cells into GSCs and prolong the median survival in mouse models of GBM with minimal normal tissue toxicity.

Project description:Despite advances in surgery and radiotherapy, glioblastoma (GBM) remains the deadliest adult brain cancer with unacceptable low median survival rates. Targeted therapies and biologics have failed to improve outcome and the standard-of-care against GBM has not changed in two decades. GBM, like many solid tumors are thought to be organized hierarchically with a small number of radiation- and chemotherapy-resistant glioma stem cells (GSCs) producing more differentiated progeny and can repopulate tumors after sublethal treatment.In this study we sought to develop novel compounds that cross the blood-brain barrier (BBB), target existing GSCs and interfere with glioma cell plasticity to prevent the induction of GSCs in response to irradiation. We show that novel urea compounds target existing GSCs, prevent the radiation-induced conversion of non-stem glioma cells into GSCs and prolong the median survival in mouse models of GBM with minimal normal tissue toxicity.

Project description:In this study, a family of porphyrins based on 5,10,15,20-Tetrakis(4-ethylphenyl)porphyrin (1, Ph) and six metallo-derivatives (Zn2+(2, Ph-Zn), Sn4+(3, Ph-Sn), Mn2+ (4, Ph-Mn), Ni2+ (5, Ph-Ni), Al3+ (6, Ph-Al), and V3+ (7, Ph-V)) were tested as photosensitizers for photodynamic therapy against Leishmania braziliensis and panamensis. The singlet oxygen quantum yield value (ΦΔ) for (1-7) was measured using 1,3-diphenylisobenzofuran (DPBF) as a singlet oxygen trapping agent and 5,10,15,20-(tetraphenyl)-porphyrin (H2TPP) as a reference standard; besides, parasite viability was estimated by the MTT assay. After metal insertion into the porphyrin core, the ΦΔ increased from 0.76-0.90 and cell viability changed considerably. The ΦΔ and metal type changed the cytotoxic activity. Finally, (2) showed both the highest ΦΔ (0.90) and the best photodynamic activity against the parasites studied (IC50 of 1.2 μM).

Project description:The melanocortin system is involved in the regulation of several complex physiological functions. In particular, the melanocortin-3 and -4 receptors (MC3R/MC4R) have been demonstrated to regulate body weight, energy homeostasis, and feeding behavior. Synthetic and endogenous melanocortin agonists have been shown to be anorexigenic in rodent models. Herein, we report synthesis and structure-activity relationship (SAR) studies of 27 nonpeptide small molecule ligands based on an unsymmetrical substituted urea core. Three templates containing key residues from the lead compounds, showing diversity at three positions (R(1), R(2), R(3)), were designed and synthesized. The syntheses were optimized for efficient microwave-assisted chemistry that significantly reduced total syntheses time compared to a previously reported room temperature method. The pharmacological characterization of the compounds on the mouse melanocortin receptors identified compounds 1 and 12 with full agonist activity at the mMC4R, but no activity was observed at the mMC3R when tested up to 100 μM concentrations. The SAR identified compounds possessing aliphatic or saturated cyclic amines at the R(1) position, bulky aromatic groups at the R(2) position, and benzyl group at the R(3) position resulted in mMC4R selectivity over the mMC3R. The small molecule template and SAR knowledge from this series may be helpful in further design of MC3R/MC4R selective small molecule ligands.

Project description:N,N'-disubstituted urea-based soluble epoxide hydrolase (sEH) inhibitors are promising therapeutics for hypertension, inflammation, and pain in multiple animal models. The drug absorption and pharmacological efficacy of these inhibitors have been reported extensively. However, the drug metabolism of these inhibitors is not well described. Here we reported the metabolic profile and associated biochemical studies of an N-adamantyl urea-based sEH inhibitor 1-adamantan-1-yl-3-(5-(2-(2-ethoxyethoxy)ethoxy)pentyl)urea (AEPU) in vitro and in vivo. The metabolites of AEPU were identified by interpretation of liquid chromatography-mass spectrometry (LC-MS), liquid chromatography-tandem mass spectrometry (LC-MS/MS) and/or NMR. In vitro, AEPU had three major positions for phase I metabolism including oxidations on the adamantyl moiety, urea nitrogen atoms, and cleavage of the polyethylene glycol chain. In a rodent model, the metabolites from the hydroxylation on the adamantyl group and nitrogen atom were existed in blood while the metabolites from cleavage of polyethylene glycol chain were not found in urine. The major metabolite found in rodent urine was 3-(3-adamantyl-ureido)-propanoic acid, a presumably from cleavage and oxidation of the polyethylene glycol moiety. All the metabolites found were active but less potent than AEPU at inhibiting human sEH. Furthermore, cytochrome P450 (CYP) 3A4 was found to be a major enzyme mediating AEPU metabolism. In conclusion, the metabolism of AEPU resulted from oxidation by CYP could be shared with other N-adamantyl-urea-based compounds. These findings suggest possible therapeutic roles for AEPU and new strategies for drug design in this series of possible drugs.

Project description:In the title compound, C(9)H(20)N(2)S, the n-butyl groups are in syn and anti positions in relation to the C=S bond. In the crystal, two mol-ecules are connected by two N-H⋯S=C hydrogen bonds into a centrosymmetric dimer. Another N-H⋯S=C hydrogen bond links the dimers, forming layers with a hydro-philic inter-ior and a hydro-phobic exterior, which spread across the (100) plane. Inter-lacing of the external butyl groups combines these layers into a three-dimensional structure.