Gemcitabine elaidate and ONC201 combination therapy for inhibiting pancreatic cancer in a KRAS mutated syngeneic mouse model.

Approximately 90% of pancreatic cancer (PC) contain KRAS mutations. Mutated KRAS activates the downstream oncogenic PI3K/AKT and MEK signaling pathways and induces drug resistance. However, targeting both pathways with different drugs can also lead to excessive toxicity. ONC201 is a dual PI3K/AKT and MEK pathway inhibitor with an excellent safety profile that targets death receptor 5 (DR5) to induce apoptosis. Gemcitabine (GEM) is a first-line chemotherapy in PC, but it is metabolically unstable and can be stabilized by a prodrug approach. In this study, phospho-Akt, phospho-mTOR, and phospho-ERK protein expressions were evaluated in patient PDAC-tissues (n = 10). We used lipid-gemcitabine (L_GEM) conjugate, which is more stable and enters the cells by passive diffusion. Further, we evaluated the efficacy of L_GEM and ONC201 in PC cells and "KrasLSL-G12D; p53LoxP; Pdx1-CreER (KPC) triple mutant xenograft tumor-bearing mice. PDAC patient tissues showed significantly higher levels of p-AKT (Ser473), p-ERK (T202/T204), and p-mTOR compared to surrounding non-cancerous tissues. ONC201 in combination with L_GEM, showed a superior inhibitory effect on the growth of MIA PaCa-2 cells. In our in-vivo study, we found that ONC201 and L_GEM combination prevented neoplastic proliferation via AKT/ERK blockade to overcome chemoresistance and increased T-cell tumor surveillance. Simultaneous inhibition of the PI3K/AKT and MEK pathways with ONC201 is an attractive approach to potentiate the effect of GEM. Our findings provide insight into rational-directed precision chemo and immunotherapy therapy in PDAC.

Anti-miR-96 and Hh pathway inhibitor MDB5 synergistically ameliorate alcohol-associated liver injury in mice.

Alcohol-associated liver disease (ALD) and its complications are significant health problems worldwide. Several pathways in ALD are influenced by alcohol that drives inflammation, fatty acid metabolism, and fibrosis. Although miR-96 has become a key regulator in several liver diseases, its function in ALD remains unclear. In contrast, sonic hedgehog (SHH) signaling has a well-defined role in liver disease through influencing the activation of hepatic stellate cells (HSCs) and the inducement of liver fibrosis. In this study, we investigated the expression patterns of miR-96 and Hh molecules in mouse and human liver samples. We showed that miR-96 and Shh were upregulated in ethanol-fed mice. Furthermore, alcoholic hepatitis (AH) patient specimens also showed upregulated FOXO3a, TGF-ß1, SHH, and GLI2 proteins. We then examined the effects of Hh inhibitor MDB5 and anti-miR-96 on inflammatory and extracellular matrix (ECM)-related genes. We identified FOXO3 and SMAD7 as direct target genes of miR-96. Inhibition of miR-96 decreased the expression of these genes in vitro in AML12 cells, HSC-T6 cells, and in vivo in ALD mice. Furthermore, MDB5 decreased HSCs activation and the expression of ECM-related genes, such as Gli1, Tgf-ß1, and collagen. Lipid nanoparticles (LNPs) loaded with the combination of MDB5, and anti-miR-96 ameliorated ALD in mice. Our study demonstrated that this combination therapy could serve as a new therapeutic target for ALD.

Targeting BRD4 and PI3K signaling pathways for the treatment of medulloblastoma.

Medulloblastoma (MB) is a malignant pediatric brain tumor which shows upregulation of MYC and sonic hedgehog (SHH) signaling. SHH inhibitors face acquired resistance, which is a major cause of relapse. Further, direct MYC oncogene inhibition is challenging, inhibition of MYC upstream insulin-like growth factor/ phosphatidylinositol-4,5-bisphosphate 3-kinase (IGF/PI3K) is a promising alternative. While PI3K inhibition activates resistance mechanisms, simultaneous inhibition of bromodomain-containing protein 4 (BRD4) and PI3K can overcome resistance. We synthesized a new molecule 8-(2,3-dihydrobenzo[b] [1, 4] dioxin-6-yl)-2-morpholino-4H-chromen-4-one (MDP5) that targets both BRD4 and PI3K pathways. We used X-ray crystal structures and a molecular modeling approach to confirm the interactions between MDP5 with bromo domains (BDs) from both BRD2 and BRD4, and molecular modeling for PI3K binding. MDP5 was shown to inhibit target pathways and MB cell growth in vitro and in vivo. MDP5 showed higher potency in DAOY cells (IC50 5.5 µM) compared to SF2523 (IC50 12.6 µM), and its IC50 values in HD-MB03 cells were like SF2523. Treatment of MB cells with MDP5 significantly decreased colony formation, increased apoptosis, and halted cell cycle progression. Further, MDP5 was well tolerated in NSG mice bearing either xenograft or orthotopic MB tumors at the dose of 20 mg/kg, and significantly reduced tumor growth and prolonged animal survival.

Recent advances in drug delivery and targeting to the brain.

Our body keeps separating the toxic chemicals in the blood from the brain. A significant number of drugs do not enter the central nervous system (CNS) due to the blood-brain barrier (BBB). Certain diseases, such as tumor growth and stroke, are known to increase the permeability of the BBB. However, the heterogeneity of this permeation makes it difficult and unpredictable to transport drugs to the brain. In recent years, research has been directed toward increasing drug penetration inside the brain, and nanomedicine has emerged as a promising approach. Active targeting requires one or more specific ligands on the surface of nanoparticles (NPs), which brain endothelial cells (ECs) recognize, allowing controlled drug delivery compared to conventional targeting strategies. This review highlights the mechanistic insights about different cell types contributing to the development and maintenance of the BBB and summarizes the recent advancement in brain-specific NPs for different pathological conditions. Furthermore, fundamental properties of brain-targeted NPs will be discussed, and the standard lesion features classified by neurological pathology are summarized.

Effect of magnesium stearate surface coating method on the aerosol performance and permeability of micronized fluticasone propionate.

In this study, we evaluated the aerodynamic performance, dissolution, and permeation behavior of micronized fluticasone propionate (FP) and magnesium stearate (MgSt) binary mixtures. Micronized FP was dry mixed with 2% w/w MgSt using a tumble mixer and a resonant acoustic mixer (RAM) with and without heating. The mixing efficacy was determined by X-ray powder diffraction (XRPD) and differential scanning calorimetry (DSC) analysis. Additional techniques were used to determine powder properties such as the dynamic vapor sorption (DVS), particle size distribution (PSD) by laser diffraction light scattering, and particle surface properties by scanning electron microscope (SEM). The aerodynamic performance was studied by the next-generation impactor (NGI) using drug-loaded capsules in a PlastiApi® device. Physiochemical properties such as porosity, particle size distribution, and surface area of the formulations were studied with adsorption and desorption curves fitted to several well-known models including Brunauer-Emmett-Teller (BET), Barret Joyner Halenda (BJH), and the density functional theory (DFT). The dissolution behavior of the formulations collected on the transwell inserts incorporated into stages 3, 5, and 7 of the NGI with a membrane providing an air interface was evaluated. Drug permeability of formulations was assessed by directly depositing particles on Calu-3 cells at the air-liquid interface (ALI). Drug concentration was determined by LC-MS/MS. A better MgSt mixing on micronized FP particles was achieved by mixing with a RAM with and without heating than with a tumble mixer. A significant concomitant increase in the % of emitted dose and powder aerosol performance was observed after MgSt mixing. Formulation 4 (RAM mixing at room temperature) showed the highest rate of permeability and correlation with dissolution profile. The results show that the surface enrichment of hydrophobic MgSt improved aerosolization properties and the dissolution and permeability rate of micronized FP by reducing powder agglomerations. A simple low-shear acoustic dry powder mixing method was found to be efficient and substantially improved the powder aerosolization properties and enhanced dissolution and permeability rate.

Polymeric nanomedicine for overcoming resistance mechanisms in hedgehog and Myc-amplified medulloblastoma.

Chemoresistance and inadequate therapeutics transport across the blood brain barrier (BBB) remain the major barriers to treating medulloblastoma (MB). Hedgehog (Hh) and IGF/PI3K pathways regulate tumor cell proliferation and resistance in MB. Current Hh inhibitors are effective initially to treat SHH-MB but acquire resistance. Herein, we showed that Hh inhibitor MDB5 and BRD4/PI3K dual inhibitor SF2523 synergistically inhibited the proliferation of DAOY and HD-MB03 cells when used in combination. Treatment of these MB cells with the combination of MDB5 and SF2523 significantly decreased colony formation and expression of MYCN, p-AKT, and cyclin D1 but significantly increased in Bax expression, compared to individual drugs. We used our previously reported copolymer mPEG-b-PCC-g-DC copolymer, which showed 8.7 ± 1.0 and 6.5 ± 0.1% loading for MDB5 and SF2523 when formulated into nanoparticles (NPs). There was sustained drug release from NPs, wherein 100% of MDB5 was released in 50 h, but only 60% of SF2523 was released in 80 h. Targeted NPs prepared by mixing 30:70 ratio of COG-133-PEG-b-PBC and mPEG-b-PCC-g-DC copolymer delivered a significantly higher drug concentration in the cerebellum at 6 and 24h after intravenous injection into orthotopic SHH-MB tumor-bearing NSG mice. Moreover, systemic administration of COG-133-NPs loaded with MDB5 and SF2523 resulted in decreased tumor burden compared to non-targeted drug-loaded NPs, without any hepatic toxicity. In conclusion, our nanomedicine of MDB5 and SF2523 offers a novel therapeutic strategy to treat chemoresistant MB.

ApoE mimetic peptide targeted nanoparticles carrying a BRD4 inhibitor for treating Medulloblastoma in mice.

Treatment of medulloblastoma (MB) is challenging due to diverse genetic make-up, chemoresistance and inefficient drug transport across the blood brain barrier (BBB). Since hedgehog (Hh) signaling regulates cancer cell proliferation and tumorigenicity, Hh inhibitors have the potential to treat sonic Hh driven MB (SHH-MB), but their repeated use develops chemoresistance due to mutations in smoothened (SMO). Herein, we aimed to overcome these problems by modulating GLI transcription using JQ1, which is a small molecule BRD4 inhibitor. JQ1 inhibited HD-MB03 and DAOY cell proliferation, with the IC50 of 402 and 4220 nM, respectively. JQ1 inhibited colony formation, but increased apoptosis in HD-MB03 and DAOY cells. Western blot analysis confirmed significant inhibition of GLI1 and c-MYC protein expression in DAOY and HD-MB03 cells, respectively. JQ1 was encapsulated into apolipoprotein (ApoE) mimetic peptide decorated nanoparticles (ApoE-NPs), with the mean particle size of 64 nm and drug loading of 10% (w/w). ApoE-NPs increased JQ1 concentration in the tumor by 5 and 8 folds at 6 and 24 h after systemic administration into orthotopic MB tumor bearing NSG mice compared to non-targeted JQ1 loaded NPs. Although there was also modest increase in JQ1 delivery to the liver, there was no hepatotoxicity as evidenced by H&E staining and little increase in serum ALT and AST after treatment with JQ1 loaded ApoE-NPs. There was also significant decrease in the orthotopic MB tumor burden after systemic administration of JQ1 loaded ApoE- NPs at the dose of 10 mg/kg every 3rd day for a total of 8 injections. In conclusion, JQ1 loaded NPs have the potential to treat Group 3 and SHH driven MB in mice.