Elucidation of Substrate Binding Interactions for Human Organic Cation Transporters 1 (SLC22A1) and 2 (SLC22A2) Using In Silico Homology Modeling in Conjunction with In Vitro Site-Directed Mutagenesis and Kinetic Analysis

Lai, Raymond E

01 January 2018

The organic cation transporters (OCTs) play a critical role in the absorption, distribution and elimination of many drugs, hormones, herbal medicines, and environmental toxins. Given the broad substrate specificity of OCTs, they fall victim to the high susceptibility for contributing to harmful drug-drug interactions. Further defining how human (h)OCTs mechanistically bind to its broad array of substrates will provide significant insight to the understanding and prediction of drug-drug interactions in polypharmacy patients and the advancement of future rational drug design for therapeutics targeting OCTs. The goal of the current study was to elucidate the critical amino acid residues for transporter-substrate binding interactions on human (h)OCT1 and 2 utilizing in silico molecular modeling techniques (homology modeling and automated docking), as well as in vitro mutagenesis and kinetic transport experiments. Three-dimensional homology models were generated for hOCT1 and 2 using Piriformospora indica phosphate transporter (PiPT) serving as template. A putative binding pocket was identified and used to dock the prototypical substrate MPP+. Docking studies revealed five residues for each transporter (hOCT1 and hOCT2) that may be critical for substrate-transporter interactions. The in silico data was used to guide subsequent in vitro site-directed mutagenesis and kinetic analysis. Four hOCT1 mutants (Gln241Lys, Thr245Lys, Tyr361Ala, and Glu447Lys) and three hOCT2 mutants (Gln242Lys, Tyr362Phe, and Tyr362Ala) showed complete loss of MPP+ transporter activity. Decreased affinity for MPP+ was observed for Phe244Ser and Thr245Ser in hOCT1, and Tyr245Ala in hOCT2. All amino acid residues highlighted in the in vitro experiments may be potentially critical for substrate-transporter interactions particularly Tyr361, Phe244 and Thr245 in hOCT1; and Tyr362 and Tyr245 in hOCT2. Docking of known structurally divergent hOCT1 and hOCT2 substrates revealed similar binding interactions as that identified for MPP+, albeit with some unique residues, suggesting the presence of a large central cavity within both transporters. Through the combination of in silico and in vitro experiments, a putative binding pocket was defined and several residues important for substrate-transporter interaction were identified and verified for hOCT1 and hOCT2. Further defining how OCTs biochemically interact with their broad array of substrates will provide significant insight to the understanding and prediction of drug-drug interactions in polypharmacy patients and the advancement of future rational drug design for therapeutics targeting OCT1 and OCT2.

Organic cation transporters

homology modeling

hepatic transport

renal transport

drug-drug interactions

Medicinal and Pharmaceutical Chemistry

Pharmaceutics and Drug Design

Understanding Medication Self-Management Capacity among Older Adults Living in Low-Income Housing Communities

Badawoud, Amal M

01 January 2019

Understanding Medication Self-Management Capacity among Older Adults Living in Low-Income Housing Communities ABSTRACT Background: Medication self-management capacity (MMC) is an individual’s cognitive and functional ability to self-administer a medication regimen as prescribed. Poor MMC is an issue in older adults often resulting in negative health outcomes and loss of independence. Therefore, understanding low-income older adults’ capacity to manage their medications may help identify individuals who are at risk for developing medication mismanagement and guide future intervention strategies based on an individual need to promote safe medication use and healthy aging in place in the community. Objectives: 1) To determine the cognitive and physical functional deficiencies in MMC among low-income older adults, 2) To identify variables that predict deficiencies in MMC in this population, 3) To determine the impact of using pharmaceutical aids/services on MMC, and 4) To examine the association between MMC and emergency room (ER) visits. Methods: This was a cross-sectional study of older adult residents living in low-income housing buildings served by the RHWP. At a study interview, information on demographics, medical history, and medication use was collected. MMC was evaluated using the Medication Management Instrument for Deficiencies in the Elderly (MedMaIDE) tool. Cognitive and functional status, health literacy and depression symptoms were assessed. ER visits were determined retrospectively over the last six months Descriptive analyses were performed to identify cognitive and physical functional deficiencies in MMC. Linear regression analysis was conducted to identify variables that predict MMC and assess the relationship between MMC and using pharmaceutical aid/service. Logistic regression analysis was used to examine the association between ER visits and MMC. Results: A total of 107 participants were included, and 89% were African-American with an average age of 68.54 years (±7.23). They had an average of 4.92 (±2.85) comorbidities and used approximately 8 (±4.12) medications on a regular basis. The mean total deficiency in medication management was 3 (±2.00) as assessed by MedMaIDE. Lacking medication knowledge was common among the participants: 69.16% could not name and 46% state the indication of all of their medications, and 38.32% did not how and when all of their medications should be taken. When controlling for ADLs and falls, the mean total deficiency score in MedMaIDE increased among those with an educational level equal to high school or less compared with participants who had a higher educational level than high school [β=1.32, 1.24, p= 0.0195, 0.0415, respectively], and participants who reported difficulty reading prescription medication labels or opening medication bottles compared with those who did not report any difficulties [β=1.18, 1.43, p= 0.0036, 0.0047, respectively]. About 20.56% of participants were receiving assistance with medications from someone, and 79.44% used at least one pharmaceutical aid/service. However, receiving assistance with medications and using pharmaceutical aid/service were not significantly associated with MMC [p= 0.5334, 0.0853, respectively]. The participants reported a total of 23 (21.5%) ER visits within six months. The adjusted model for age, educational level, number of comorbidities, and ADLs suggested that for every one-unit increase in the total deficiency score, the odds of ER visits increased by 1.23 (p=0.1809) times. Conclusion: Many older adults who lived in low-income housing had impaired capacity to manage their medications independently. They appeared to have inadequate medication knowledge, which affects their cognitive ability to manage medications. Low educational level and health literacy and reporting trouble reading labels or opening medication bottles were predictors to deficient MMC. Future studies are needed to confirm whether or not MMC predicts those who may not able to remain living independently safely or who may need additional support with medications to remain independent.

Medication self-management capacity

Medication management capacity

Medication self-administration capacity

Self-medication capacity

Medication management skills

Medication management assessments

Pharmacy and Pharmaceutical Sciences

MULTI-COMPONENT MICROPARTICULATE/NANOPARTICULATE DRY POWDER INHALATION AEROSOLS FOR TARGETED PULMONARY DELIVERY

Li, Xiaojian

01 January 2014

The aim of the work was to design, manufacture, and characterize targeted multi-component dry powder aerosols of (non-destructive) mucolytic agent (mannitol), antimicrobial drug (tobramycin or azithromycin), and lung surfactant mimic phospholipids (DPPC:DPPG=4:1 in molar ratio). The targeted dry powder for inhalation formulation for deep lung delivery with a built-in rationale of specifically interfering several disease factors of chronic infection diseases in deep lungs such as cystic fibrosis, pneumonia, chronic bronchitis, and etc. The dry powder aerosols consisting of selected chemical agents in one single formulation was generated by using spray drying from organic solution. The physicochemical properties of multi-component dry powder inhaler (DPI) formulation were characterized by a number of techniques. In addition, the in vitro aerosol dispersion performance, storage stability test, and in vitro drug release of selected spray-dried (SD) multi-component systems were conducted. The physicochemical study revealed that multi-component aerosol particles possessed essential particle properties suitable for deep lung delivery. In general, the multi-component particles (typically 0.5 to 2 µm) indicated that the designed SD aerosol particles could potentially penetrate deep lung regions (such as respiratory bronchiolar and alveolar regions) by sedimentation and diffusion, respectively. The essential particle properties including narrow size distribution, spherical particle and smooth surface morphologies, and low water content (or water vapor sorption) could potentially minimize interparticulate interactions. The study of in vitro aerosol dispersion performance showed that majority of SD multi-component aerosols exhibited low values (less than 5µm) of MMAD, high values (approximately above 30% up to 60.4%) of FPF, and high values (approximately above 90%) of ED, respectively. The storage stability study showed that azithromycin–incorporated multi-component aerosol particles stored at 11 and 40% RH with no partial crystallization were still suitable for deep lung delivery. Compared to SD pure azithromycin particles, the azithromycin-incorporated multi-component particles exhibited an enhanced initial release. The targeted microparticulate and nanoparticulate multi-component dry powder aerosol formulations with essential particle properties for deep lung pulmonary delivery were successfully produced by using spray drying from organic solution. The promising experimental data suggest the multi-component formulations could be further investigated in in vivo studies for the purpose of commercialization.

aerosol dispersion performance

dry powder inhaler (DPI)

spray drying

physicochemical characterization

Medicinal Chemistry and Pharmaceutics

Pharmaceutics and Drug Design

INFLUENCE OF ONCOTYPE DX® ON CHEMOTHERAPY PRESCRIBING IN EARLY STAGE BREAST CANCER PATIENTS: A CLAIMS-BASED EVALUATION OF UTILIZATION IN THE REAL WORLD

Kennedy, Kenneth Neil

01 January 2012

The decision for adjuvant therapy in women with early stage breast cancer (ESBC) has historically been guided by the presence or absence of specific biological markers (hormone and HER2 receptors), age, and extent of nodal involvement. Oncotype DX® is a validated assay that quantifies protein expression that can predict the risk of cancer recurrence. This study evaluates if the use of Oncotype DX® impacts chemotherapy prescribing in ESBC. This retrospective, cohort study identified patients with ESBC from a large commercially insured population from January 2007 through June 2009. Patients were identified as having ESBC by utilizing procedure and diagnosis codes to indicate that a sentinel lymph node biopsy had been performed. Hormone receptor status was verified by patients receiving at least one month of hormonal therapy including: tamoxifen, anastrozole, letrozole, or exemestane. Exclusion criteria will include patients less than 18 years of age, procedure codes indicating axillary lymph node dissection, or charges for trastuzumab. The administration of Oncotype DX® was not found to significantly affect a physician’s decision to prescribe chemotherapy. However, there were significant regional differences in Oncotype DX® utilization by region. Future studies should be conducted at a population level to determine the effects of Oncotype DX®.

Oncotype DX®

breast cancer

early-stage

adjuvant

chemotherapy

Health and Medical Administration

Oncology

Therapeutics

Application of Mixed-Effect Modeling to Improve Mechanistic Understanding and Predictability of Oral Absorption

Bergstrand, Martin

January 2011

Several sophisticated techniques to study in vivo GI transit and regional absorption of pharmaceuticals are available and increasingly used. Examples of such methods are Magnetic Marker Monitoring (MMM) and local drug administration with remotely operated capsules. Another approach is the paracetamol and sulfapyridine double marker method which utilizes observed plasma concentrations of the two substances as markers for GI transit. Common for all of these methods is that they generate multiple types of observations e.g. tablet GI position, drug release and plasma concentrations of one or more substances. This thesis is based on the hypothesis that application of mechanistic nonlinear mixed-effect models could facilitate a better understanding of the interrelationship between such variables and result improved predictions of the processes involved in oral absorption. Mechanistic modeling approaches have been developed for application to data from MMM studies, paracetamol and sulfapyridine double marker studies and for linking in vitro and in vivo drug release. Models for integrating information about tablet GI transit, in vivo drug release and drug plasma concentrations measured in MMM studies was outlined and utilized to describe drug release and absorption properties along the GI tract for felodipine and the investigational drug AZD0837. A mechanistic link between in vitro and in vivo drug release was established by estimation of the mechanical stress in different regions of the GI tract in a unit equivalent to rotation speed in the in vitro experimental setup. The effect of atropine and erythromycin on gastric emptying and small intestinal transit was characterized with a semi-mechanistic model applied to double marker studies in fed and fasting dogs. The work with modeling of in vivo drug absorption has highlighted the need for, and led to, further development of mixed-effect modeling methodology with respect to model diagnostics and the handling of censored observations.

Absorption

magnetic marker monitoring

drug release

IVIVC

pharmacometrics

NONMEM

model diagnostics

pcVPC

pvcVPC

visual predictive check

VPC

BQL

paracetamol

sulfapyridine.

Other pharmacy

Övrig farmaci

Microspheres for Liver Radiomicrospheres Therapy and Planning

Amor-Coarasa, Alejandro

28 June 2013

Liver cancer accounts for nearly 10% of all cancers in the US. Intrahepatic Arterial Radiomicrosphere Therapy (RMT), also known as Selective Internal Radiation Treatment (SIRT), is one of the evolving treatment modalities. Successful patient clinical outcomes require suitable treatment planning followed by delivery of the microspheres for therapy. The production and in vitro evaluation of various polymers (PGCD, CHS and CHSg) microspheres for a RMT and RMT planning are described. Microparticles with a 30±10 µm size distribution were prepared by emulsion method. The in vitro half-life of the particles was determined in PBS buffer and porcine plasma and their potential application (treatment or treatment planning) established. Further, the fast degrading microspheres (≤ 48 hours in vitro half-life) were labeled with 68Ga and/or 99mTc as they are suitable for the imaging component of treatment planning, which is the primary emphasis of this dissertation. Labeling kinetics demonstrated that 68Ga-PGCD, 68Ga-CHSg and 68Ga-NOTA-CHSg can be labeled with more than 95% yield in 15 minutes; 99mTc-PGCD and 99mTc-CHSg can also be labeled with high yield within 15-30 minutes. In vitro stability after four hours was more than 90% in saline and PBS buffer for all of them. Experiments in reconstituted hemoglobin lysate were also performed. Two successful imaging (RMT planning) agents were found: 99mTc-CHSg and 68Ga-NOTA-CHSg. For the 99mTc-PGCD a successful perfusion image was obtained after 10 minutes, however the in vivo degradation was very fast (half-life), releasing the 99mTc from the lungs. Slow degrading CHS microparticles (> 21 days half-life) were modified with p-SCN-b-DOTA and labeled with 90Y for production of 90Y-DOTA-CHS. Radiochemical purity was evaluated in vitro and in vivo showing more than 90% stability after 72 and 24 hours respectively. All agents were compared to their respective gold standards (99mTc-MAA for 68Ga-NOTA-CHSg and 99mTc-CHSg; 90Y-SirTEX for 90Y-DOTA-CHS) showing superior in vivo stability. RMT and RMT planning agents (Therapy, PET and SPECT imaging) were designed and successfully evaluated in vitro and in vivo.

Liver

cancer

lung

perfusion

PET

SPECT

microspheres

68Ga

radiomicrospheres

99mTc

90Y

Cardiology

Oncology

Pharmaceutics and Drug Design

Radiochemistry

The Development of Novel Apurinic/Aprymidinic Endonuclease/Redox-factor 1 Inhibitors for the Treatment of Human Melanoma

Sharifi, Bella

19 December 2019

Apurinic/apyrimidinic DNA repair endonuclease-1 (APE1), first recognized as an important DNA excision repair enzyme, is also known as Redox Factor-1 (Ref-1) involved in the activation of many nuclear transcription factors in both redox-dependent and independent manner. It has been well-documented that the overexpression of APE/Ref-1 contributes to the development of chemo-resistance and is associated with tumor progression in many human malignancies [1]. Our previous study in melanoma demonstrated that the development of novel inhibitors targeting the redox regulation domain of APE/Ref-1 is a promising strategy for melanoma treatment. To date, limited successes have been reported in developing novel APE/Ref-1 inhibitors for cancer treatment. Utilizing a structure-based approach, our study identified and characterized small molecular inhibitors of APE/Ref-1. First, N-terminally truncated APE/Ref-1 protein lacking the first 40 amino acid residues (∆40APE-1wt) was cloned into the pGEX-6P1 vector to express the GST-∆40APE-1wtprotein. After cleavage of GST-tag, the concentrated ∆40APE-1wt protein was subjected to protein crystallization study. We have successfully diffracted ∆40APE-1wt crystals and collected data with a resolution of 1.57Å. The crystal structure was further determined by molecular replacement in Molrep using the already available human APE-1 structure (PDB: 5CFG). For the first time, we observed the dimerization of APE/Ref-1 protein formed under oxidative conditions, which may contribute to the redox regulation of APE/Ref-1. Such structural transformation of APE/Ref-1 protein under distinct redox conditions may pave the way for future drug development and optimization. The binding affinity of the candidate compounds with ∆40APE-1wt protein was also determined using Surface Plasmon Resonance (SPR), and the Ki values were analyzed. One of the potent inhibitors developed by our group by structure-based approach, exhibited promising anti-melanoma activities both in vitro and in vivo. Future studies on the structure-activity association are warranted.

Structural Biology

Protein Crystallography

Drug Design Delivery

Medical Cell Biology

Medical Molecular Biology

Medical Pharmacology

Pharmaceutics and Drug Design

Skin and Connective Tissue Diseases

PHOSPHATIDYLINOSITOL 3-KINASE (PI3K) AS A THERAPEUTIC TARGET IN NSCLC

Stamatkin, Christopher W.

01 January 2014

Deregulated activation of phosphatidylinositol 3-kinase (PI3K) pathway is central to many human malignancies. The functions of this pathway are critical for normal cell metabolism, proliferation, and survival. In lung cancers, the PI3K pathway activity is often aberrantly driven by multiple mutations, including EGFR, KRAS, and PIK3CA. Molecules targeting the PI3K pathway are intensely investigated as potential anti-cancer agents. Although inhibitors of the pathway are currently in clinical trials, rational and targeted use of these compounds, alone or in combination, requires an understanding of isoform-specific activity in context. We sought to identify class IA PI3K enzyme (p110a/PIK3CA, p110b/PIK3CB, p110d/PIK3CD) activities using isoform-specific inhibitors in a lung cancer model system. Treatment of non-small cell lung cancer (NSCLC) cell lines with PIK3CA, PIK3CB, PIK3CD or PIK3CB/D inhibitors resulted in pharmacokinetic and pharmacodynamic responses that frequently tracked with a specific mutation status. Activation of PIK3CA dictated response to the PIK3CA-specific inhibitor while deletion of PTEN phosphatase indicated response to the PIK3CB inhibitor. The PIK3CD isoform-specific inhibitors lacked efficacy in all NSCLC cell lines tested, however treatment at increased concentrations likely provide concurrent inhibition of both PIK3CB/D isoforms improving activity of either agent alone but did not track with a single biomarker. The observed pharmacodynamic and proliferation responses to isoform-specific inhibitors suggested that PI3K isoforms may functionally compensate for loss of another in certain genetic backgrounds. These studies demonstrate unanticipated cellular responses to PI3K isoform inhibition in NSCLC, suggesting that patient populations with specific mutations can benefit from certain isoform-selective inhibitors, or combinations, allowing for rational and targeted clinical use of these agents.

PI3K

NSCLC

drug discovery

targeted therapy

lung cancer

Medical Cell Biology

Medical Genetics

Medical Pharmacology

Medicinal Chemistry and Pharmaceutics

Oncology

Pharmaceutics and Drug Design

GLYCOSAMINOGLYCAN LYASES IN THE PREPARATION OF OLIGOSACCHARIDES

Alabbas, Alhumaidi B

01 January 2018

Glycosaminoglycans are heterogeneous polysaccharides that mediate important biological functions. There has been considerable interest in deciphering the precise GAG sequences that are responsible for protein interactions. In fact, several GAG oligosaccharides have been discovered to date as targeting proteins with higher level of specificity. Yet, it has been difficult to develop GAG oligosaccharides as drugs. One of the key reasons for this state of art is that GAG synthesis is extremely challenging and is highly structure-specific. Thus, much of the biology and pharmacology of GAG remains unknown and unexploited to date. An alternative approach is to prepare GAG oligosaccharides using enzymatic depolymerization of polymeric GAGs. GAG lyases, including heparinases and chondritinases represent powerful tools that can theoretically generate multiple oligosaccharides in parallel. However, it is difficult to implement such procedures with high consistency. Moreover, GAG lyases can digest GAGs down to disaccharides. A priori, non-polymeric GAGs, or alternatively GAG oligosaccharides containing 4 to 10 residues, would be expected to function better as therapeutic agents because they would be more homogeneous and less non-specific than their polymeric precursors. Thus, we reasoned that immobilization of these enzymes may engineer altered biopolymer processing, which may afford longer oligosaccharides in higher proportions and greater consistency. Heparinase-I and chondroitinase ABC were immobilized on CNBr-activated Sepharose and compared with the free form of the enzyme. Immobilized GAG lyases retained high efficiency of depolymerization over a wide range of pH, temperature and reusability. Most importantly, the immobilized enzyme was found to produce larger proportions of oligosaccharides longer than di- and tetra-saccharides as compared to lyases in the free form. A two dimensional separation involves size exclusion chromatography followed by reversed phase ion-pairing ultra performance liquid chromatography coupled to electrospray ionization mass spectrometry was employed to separate and characterize oligosaccharide structures. We have identified 40 heparin oligosaccharides, including regular and rare structures ranging from dp4 to dp10 and 39 chondroitin sulfate oligosaccharides in high homogeneity and significant yields. Overall, this technology is likely to offer a simple and cost effective route to preparation of larger amounts of sequences that can be expected to bind and modulate protein function.

Glycosaminoglycan

Heparin

Heparinases

Chondroitin sulfate

Chondroitinase ABC

Immobilization

Carbohydrates

Enzymes and Coenzymes

Macromolecular Substances

Medicinal and Pharmaceutical Chemistry

Other Medical Sciences

Pharmaceutical Preparations

Pharmaceutics and Drug Design

Therapeutics

Economic Burden of Renal Cell Carcinoma (RCC) and Treatment Patterns, Overall Survival and Healthcare Costs among Older Metastatic RCC Patients

Kale, Hrishikesh P

01 January 2018

Background Renal cell carcinoma (RCC) is the most common type of kidney cancer. Patients diagnosed with metastatic RCC (mRCC) have shorter overall survival compared to those diagnosed at earlier stages. Several targeted therapies, which cost from $7,000 - $16,000 per month have been approved since 2005 to treat mRCC. In addition, there is a growing interest in the use of cytoreductive nephrectomy (CN) with targeted therapies among mRCC patients. However, little is known regarding the economic burden of RCC and role of CN and prescribing patterns of targeted therapies among older mRCC patients. Objectives 1) To assess the economic burden of RCC among older adults in the targeted therapy era 2) To compare the overall survival (OS) and total healthcare cost (THC) among older mRCC patients receiving CN and targeted therapy versus patients receiving targeted therapy alone 3) To describe prescribing patterns of targeted therapies and associated OS and THC among older mRCC patients. Methods This dissertation was conducted using the Surveillance Epidemiology and End Results (SEER) - Medicare linked data. For the first objective, the study included a prevalent cohort of RCC patients from 2013, diagnosed during 2005 - 2013 and continuously enrolled in Medicare. RCC patients were matched to non-cancer beneficiaries using propensity score matching. Generalized linear models estimated the incremental healthcare costs. Incremental total healthcare cost (THC) was multiplied by the estimated number of RCC patients on Medicare to calculate the total economic burden of RCC. For the second objective, we included patients diagnosed with mRCC between 2007-2014 and compared overall survival (OS), and THC between patients who received CN + targeted therapy and targeted therapy alone. A propensity score based inverse probability of treatment weighting (IPTW) method was used to balance the two treatment groups. A Cox proportional hazard model assessed the risk for death and a GLM compared healthcare costs between the groups. For the third objective, patients with mRCC were defined as patients who were diagnosed at stage-IV or at earlier stages but were currently using targeted therapies. Further, we restricted our sample to patients who initiated targeted therapy. We described the frequencies of the most common first and second line targeted therapies. We also described OS and THC per month for clear-cell and non-clear cell mRCC for each therapy and line of therapy. Results The first study included 10,392 each of RCC and control patients. The average THC associated with RCC was $7,419. The average THC was $4,584 for patients diagnosed at stage-I, $4,727 for stage-II, $9,331 for stage-III, and $31,637 for stage-IV. The annual economic burden of RCC on Medicare was estimated to be $1.5 billion. The second study included 471 mRCC patients that received CN + targeted therapy or targeted therapy alone. The median OS from the adjusted survival curves was significantly higher (p Conclusions The economic burden of RCC varied substantially between early stage and metastatic patients. Among mRCC patients, use of CN among targeted therapy users was associated with a higher median OS and similar monthly THC over a lifetime. Sunitinib and everolimus were the most common first and second line targeted therapies among mRCC patients. The descriptive analysis suggested that OS and THC were similar across types of targeted therapy sequences.

Renal cell carcinoma

metastatic renal cell carcinoma

economic burden

targeted therapy

nephrectomy

healthcare cost

survival

Epidemiology

Health Services Research

Oncology