Haitham AlRabiah

Hyaluronic Acid Coated Chitosan Nanoparticles Reduced the Immunogenicity of the Formed Protein Corona

Studying the interactions of nanoparticles (NPs) with serum proteins is necessary for the rational development of nanocarriers. Optimum surface chemistry is a key consideration to modulate the formation of the serum protein corona (PC) and the resultant immune response. We investigated the constituent of the PC formed by hyaluronic acid-coated chitosan NPs (HA-CS NPs). Non-decorated chitosan NPs (CS NPs) and alginate-coated chitosan NPs (Alg-CS NPs) were utilized as controls. Results show that HA surface modifications significantly reduced protein adsorption relative to controls. Gene Ontology analysis demonstrates that HA-CS NPs were the least immunogenic nanocarriers. Indeed, less inflammatory proteins were adsorbed onto HA-CS NPs as opposed to CS and Alg-CS NPs. Interestingly, HA-CS NPs differentially adsorbed two unique anti-inflammatory proteins (ITIH4 and AGP), which were absent from the PC of both controls. On the other hand, CS and Alg-CS NPs selectively adsorbed a proinflammatory protein (Clusterin) that was not found on the surfaces of HA-CS NPs. While further studies are needed to investigate abilities of the PCs of only ITIH4 and AGP to modulate the interaction of NPs with the host immune system, our results suggest that this proof-of-concept could potentially be utilized to reduce the immunogenicity of a wide range of nanomaterials.

LC-MS/MS reveals the formation of reactive ortho -quinone and iminium intermediates in saracatinib metabolism: Phase I metabolic profiling

Saracatinib (AZD-0530) is a drug under clinical trials that developed by AstraZeneca. It is considered a dual kinase inhibitor, with selective actions as a Src inhibitor and a Bcr-Abl tyrosine-kinase inhibitor. Saracatinib chemical structure contains N-methyl piperazine group and 1,3 benzodioxole group. N-methyl piperazine group that can be bioactivated to form iminium intermediates which can be captured by KCN. 1,3-Benzodioxole group can be bioactivated to form ortho-quinone intermediate that can be conjugated with GSH. The formed conjugates are stable and can be identified using LC-MS/MS. In our current work, we are trying to give insight into the reasons that may be responsible for saracatinib side effects. Using LC-MS/MS, in vitro metabolic pathways were investigated for saracatinib in rat liver microsomes. Ten saracatinib phase I metabolites were characterized and the metabolic pathways were found to be hydroxylation, oxidation, reduction, dealkylation, N-oxidation and ether cleavage. Also, four potential reactive intermediates (three cyanide adducts and one GSH conjugate) were identified and the bioactivation mechanisms were explained. The existence of these four reactive metabolites may be the main reason for observed saracatinib side effects in clinical trials. Literature review showed no previous articles have been proposed the detailed structural identification of the formed reactive metabolites.

Biophysical and In Silico Studies of the Interaction between the Anti-Viral Agents Acyclovir and Penciclovir, and Human Serum Albumin

Acyclovir (ACV) and penciclovir (PNV) have been commonly used during the last few decades as potent antiviral agents, especially for the treatment of herpes virus infections. In the present research their binding properties with human serum albumin (HSA) were studied using different advanced spectroscopic and in-silico methods. The interactions between ACV/PNV and HSA at the three investigated temperatures revealed a static type of binding. Extraction of the thermodynamic parameters of the ACV-HSA and PNV-HSA systems from the measured spectrofluorimetric data demonstrated spontaneous interactions with an enthalpy change (∆H0) of −1.79 ± 0.29 and −4.47 ± 0.51 kJ·mol−1 for ACV and PNV, respectively. The entropy change (∆S0) of 79.40 ± 0.95 and 69.95 ± 1.69 J·mol−1·K−1 for ACV and PNV, respectively, hence supported a potential contribution of electrostatic binding forces to the ACV-HSA and PNV-HSA systems. Putative binding of ACV/PNV to HSA, using previously reported site markers, showed that ACV/PNV were bound to HSA within subdomains IIA and IIIA (Sudlow sites I and II). Further confirmation was obtained through molecular docking studies of ACV-HSA and PNV-HSA binding, which confirmed the binding site of ACV/PNV with the most stable configurations of ACV/PNV within the HSA. These ACV/PNV conformers were shown to have free energies of −25.61 and −22.01 kJ·mol−1 for ACV within the HSA sites I and II and −22.97 and −26.53 kJ·mol−1 for PNV in HSA sites I and II, with hydrogen bonding and electrostatic forces being the main binding forces in such conformers.

A reliable and stable method for the determination of foretinib in human plasma by LC-MS/MS: Application to metabolic stability investigation and excretion rate:

Foretinib (GSK1363089) is a multiple receptor tyrosine kinases inhibitor. In this study, a reliable, fast liquid chromatography–tandem mass spectrometric method was described for assaying foretinib in plasma, urine, and rat liver microsome samples. Simple extraction procedure by protein preciptation with acetonitrile was implemented for foretinib and brigatinib (internal standard) analysis. Chromatographic resolution of analytes was achieved on C18 column with the help of isocratic mobile phase. The binary mobile phase consisted of 60% ammonium formate (10 mM, pH 4.2) and 40% acetonitrile at a flow rate of 0.25 mL/min. Run time was 3 min, and both foretinib and brigatinib were eluted within 0.74 and 1.95 min; they were detected in positive ion mode utilizing multiple reactions monitoring mode. Linearity of the proposed method ranged from 5 to 500 ng/mL (r2 ≥ 0.9993) in the human plasma. Lower limit of quantification and detection were 6.0 and 1.8 ng/mL, respectively. Intraday and interday precision and accuracy were 0.16 to 1.67 % and −2.39 to −0.52 %. In vitro half-life and intrinsic clearance were 24.93 min and 6.56 mL/min/kg, respectively. Literature review showed that no previous studies have been proposed for the analytical quantification of foretinib in human plasma or its metabolic stability. The established method was also applied to estimate the rate of foretinib excretion in rat urine. The developed method can be used for foretinib pharmacokinetic applications.

Development and validation of HPLC-MS/MS method for the determination of lixivaptan in mouse plasma and its application in a pharmacokinetic study

The aim of the present study was to develop a simple, sensitive and accurate liquid chromatography-electrospray ionization tandem mass spectrometry (ESI-MS/MS) method for the determination of lixivaptan (LIX) in mouse plasma using vildagliptin as the internal standard (IS). A precipitation procedure was used for the extraction of LIX and vildagliptin from mouse plasma. Chromatographic separation of LIX was achieved using a C18 analytical column (50 × 2.1 mm, 1.8 μm) at 25°C. The mobile phase comprised acetonitrile and ammonium formate (10 mm, pH 3.1; 40:60, v/v) pumped at a flow rate of 0.3 mL min-1 . A tandem mass spectrometer with an electrospray ionization source was used to perform the assay. Quantification of LIX at m/z 290 → 137 and IS at 154 → 97 was attained through multiple reaction monitoring. The investigated method was authenticated following the bio-analytical method of validation guidelines of the US Food and Drug Administration. The developed method showed a good linearity over the concentration range from 5 to 500 ng mL-1 , and the calibration curve was linear (r = 0.9998). The mean recovery of LIX from mouse plasma was 99.2 ± 0.68%. All validation parameters for LIX were within the levels required for acceptance. The proposed method was effectively used for a pharmacokinetic study of LIX in mouse plasma.

Automated flow fluorescent noncompetitive immunoassay for measurement of human plasma levels of monoclonal antibodies used for immunotherapy of cancers with KinExA™ 3200 biosensor

This study describes, for the first time, the development of an automated sensitive flow fluorescent noncompetitive immunoassay based on kinetic-exclusion analysis (KinExA) for the quantitative determination of human plasma levels of monoclonal antibodies (mAbs) used for cancer immunotherapy. The assay was adapted on KinExA™ 3200 biosensor and optimized and validated for bevacizumab (BEV) and cetuximab (CET), as representative examples of the mAbs, using their specific antigens. These antigens were the human vascular endothelial growth factor (VEGF) and epidermal growth factor receptor (EGFR) for BEV and CET, respectively. The limits of detection were 1.28 and 52.64 ng mL-1 for BEV and CET, respectively. The accuracy of the assay was demonstrated with analytical recovery of analytes from spiked plasma at 96.2-104.3 and 96.8-105.3% for BEV and CET, respectively. The precision of the assay was satisfactory as shown by relative standard deviation (RSD) at 2.2-5.7 and 2.5-6.1% for assay of BEV and CET, respectively. The high sensitivity of the assay allowed the use of very small volumes (~ 1 µL) of plasma sample for analysis. Automated analysis by the proposed KinExA-based assay facilitates the processing of large numbers of mAbs-containing specimens in studies of pharmacokinetics (PK), pharmacodynamics (PD), and therapeutic drug monitoring (TDM) of therapeutic mAbs. The proposed assay can be used to overcome the problems encountered in the existing conventional immunoassays for mAbs.

Development and validation of generic heterogeneous fluoroimmunoassay for bioanalysis of bevacizumab and cetuximab monoclonal antibodies used for cancer immunotherapy

This study describes, for the first time, the development and validation of a highly selective and sensitive heterogeneous fluoroimmunoassay (FIA) for the bioanalysis of two monoclonal antibodies (mAbs) used for cancer immunotherapy: bevacizumab (BEV) and cetuximab (CET). The assay combines reliable non-competitive binding of BEV and CET to their specific cell receptor proteins (human vascular endothelial growth factor (VEGF) and epidermal growth factor receptor (EGFR), respectively) with the highly specific fluorescence activity of the fluorescein isothiocyanate labeled anti-human IgG (FITC-IgG) used as label. The limits of detection were 14.14 and 1.27 × 103 ng mL-1 for BEV and CET, respectively. The accuracy and precision of the assay were demonstrated. The assay is simple, convenient, and requires very small volume (~ 5 µL) of plasma sample for analysis. The assay can offer high throughput analysis in clinical settings when modern microplates of multiplies of 96 (up to 6144-wells) are used and/or integrated as a part of automated robotic system. The proposed assay can be used for routine clinical bioanalysis of mAbs with potential application in pharmacokinetics, pharmacodynamics and therapeutic drug monitoring (TDM).

LC–MS/MS reveals the formation of iminium and quinone methide reactive intermediates in entrectinib metabolism: In vivo and in vitro metabolic investigation

HIGHLIGHTSSeven in vitro phase I metabolites were characterized for entrectinib.Five in vivo phase I metabolites and one in vivo phase II metabolite were characterized for entrectinib.Four reactive metabolites were characterized by LC–MS/MS.Two different bioactivation pathways were identified and mechanisms were proposed.Two nucleophiles were used to capture reactive metabolites. ABSTRACT Entrectinib (RXDX‐101) is orally available inhibitor of the tyrosine kinases including tropomyosin receptor kinases (Trk) A–C, C‐ros oncogene 1 (ROS1) and anaplastic lymphoma kinase (ALK), with potential antineoplastic activity. Entrectinib (ENB) granted breakthrough designation by FDA for NTRK + Solid tumors. In vitro metabolism of ENB generates quinone methide and iminium reactive intermediates that were captured by potassium cyanide and GSH, respectively forming stable conjugates that were characterized by LC–MS/MS. Seven in vitro ENB metabolites were identified through four metabolic reactions including hydroxylation, N‐dealkylation, N‐oxidation and reduction. Furthermore, four reactive intermediates including two quinone methide and two iminium ions were detected and the bioactivation mechanisms were supposed. In vivo metabolism of ENB was done by giving single oral dose (35.2 mg/kg) to Sprague Dawley rats. In vivo metabolism generates five phase I metabolites similar to in vitro metabolism except no metabolic reactions were identified on indazole ring. One phase II metabolite was characterized in in vivo metabolism of ENB resulted from glucuronidation of hydroxyl metabolite of ENB. Reporting these data for ENB is very crucial in the development stage. Reviewing literatures revealed the absence of previous articles have been done for the ENB in vitro or in vivo metabolism study or structural characterization of the formed reactive intermediates.

The status of licensed pharmacy workforce in Saudi Arabia: a 2030 economic vision perspective

BackgroundThe economy of Saudi Arabia is currently undergoing a major transformation which will have an impact on employment in the pharmacy sector. However, quantitative data characterizing the pharmacy workforce in the Kingdom are currently not available. Therefore, the aim of this study was to determine the current status of the licensed pharmacy workforce in the pharmacy field in Saudi Arabia.MethodsDescriptive statistics were performed on data from the Saudi Commission for Health Specialties (SCFHS) as of March 2017.ResultsThe labor market for pharmacists in Saudi Arabia is dominated by expatriates. Saudi nationals constitute less than 20% of the pharmacists employed in the Kingdom. The underemployment of Saudis is most evident in the largest sectors of the pharmacy field, namely, private health care establishments, community pharmacies, and pharmaceutical companies.ConclusionThere is an unmet need to train Saudi citizens as pharmacists and retain them in the workforce. Addressing this issue should become an important objective in Saudi Arabia’s Vision for 2030.

LC-ESI-MS/MS identification and characterization of ponatinib in vivo phase I and phase II metabolites

Ponatinib (Iclusig®) is a multi-targeted tyrosine kinase inhibitor (TKIs). It is active against T315I and other BCR-ABL mutants. Investigation of in vivo metabolism of ponatinib was done using Sprague Dawley rats by giving one oral dose of PNT (4.7 mg/kg) to each rat and urine samples were gathered at several time intervals from dosing. Filteration of urine samples was done through 0.45 μm syringe filters. Phase separation using ACN was applied for extraction of ponatinib related metabolites. Characterization and identification of one in vivo phase II metabolite and thirteen in vivo phase I of PNT were done using LC-MS/MS. Phase I metabolic reactions were reduction, N-demethylation, hydroxylation, N-oxidation, oxidation and amide hydrolysis. Phase II metabolic reaction was glucuronidation of hydroxyl benzyl metabolites of ponatinib. The major in vivo metabolic reactions were α hydroxylation and α oxidation at piperazine ring. Literature review revealed no articles that have been published on in vivo metabolism of ponatinib in Sprague Dawley rats or ponatinib in vivo phase I and phase II metabolites structural characterization and identification.