The effect of phosphorylation on the function of P-glycoprotein

Goodfellow, Hugh Robin

January 1995

No description available.

615.1

Multi-drug resistance

Molecular interactions of P-glycoprotein

Taylor, Jenny Carmeron

January 1997

No description available.

615.1

Is there an association between trimethoprim-sulfamethoxazole use as prophylaxis and multi-drug resistant non-typhoidal salmonella? A secondary data analysis of antibiotic co-resistance surveillance data in South Africa - 2003-2005

Nanoo, Ananta

10 March 2011

MSc (Med), Epidemiology and Biostatistics, Faculty of Health Sciences, University of the Witwatersrand / Introduction Given the increasing prevalence of non-typhoidal salmonella in humans, especially as an opportunistic illness associated with HIV, enhanced surveillance for non-typhoidal salmonella (NTS), including screening for antibiotic resistance, is conducted annually in South Africa. We aimed to determine whether there is an association between trimethoprim-sulfamethoxazole (TMP-SMX) prophylaxis and multi-drug resistant NTS infection, to establish whether various factors modify the relationship between TMP-SMX resistance and invasive NTS infection, to examine whether these associations vary by province, and to quantify the resistance rates of NTS to a range of antibiotics. Methods This study was a secondary analysis of enhanced surveillance data on NTS collected between 2003 and 2005. We used descriptive methods to assess the prevalence of NTS by year, province and serotype, and to determine the prevalence of four MDR patterns. Univariate and multivariate regression models were used to investigate the relationships between TMP-SMX prophylaxis and MDR NTS. Univariate logistic regression was used to assess the relationship between invasive NTS and TMP-SMX resistance. Results TMP-SMX prophylaxis is associated with the ACKSSuT pattern (OR 1.91, 95% CI 1.14 – 3.19, p=0.0080) and the AKSSuT MDR pattern (OR 2.00, 95% CI 1.26 – 3.15, p=0.0015). Being on TMP-SMX prophylaxis is associated with an increased odds of having at least one of the four MDR patterns investigated (OR 1.43, 95% CI 1.00 – 2.04, p=0.0388). We also found high rates of resistance to all antibiotics tested except for ciprofloxacin and imipenem. The highest resistance rate was observed for sulfamethoxazole (>75.85%). S. enterica Isangi isolates showed the highest levels of resistance, with 94.43% having at least one MDR pattern. Other factors significantly associated with MDR NTS were ESBL production, prior treatment with antibiotics, HIV status and resistance to TMP-SMX. Discussion and conclusions Isolates from patients on TMP-SMX prophylaxis were associated with an increased odds of having the ACKSSuT and AKSSuT MDR patterns, not taking into account other explanatory factors. These associations did not remain significant when possible confounders were taken into account. Despite the threat of increased multi-drug resistance, TMP-SMX prophylaxis remains important in certain clinical settings.

multi-drug resistance

antibiotic resistance

non-typhoidal salmonella

EMERGENCE AND MECHANISMS OF MULTI-DRUG RESISTANT MICROORGANISMS IN PATIENTS AT HIGH RISK FOR ANTIMICROBIAL RESISTANCE

Mech, Eugene

January 2021

Antimicrobial resistance (AMR) poses a substantial threat to public health and clinical medicine. By 2050, it’s predicted that AMR will be responsible for a yearly mortality rate of 10 million people, surpassing the mortality of cancer. Despite this daunting future we face, there are many efforts currently employed to combat the growth of AMR. One significant effort involves surveillance and early identification of novel resistant bacteria circulating in high antibiotic exposure environments. The second chapter of this thesis focuses on sampling 25 patients from a hospital environment, rich with antibiotics, to build a collection of AMR bacteria that will be tested and added to surveillance efforts/future study. This chapter allowed for the identification of several worrying AMR bacteria that provide greater insights into circulating AMR in Canadian hospitals and their patients. From the AMR collection created in chapter 2, we are also able to advance our scientific understanding of how antibiotic resistance develops within us and causes issues with treatment. In chapter 3, we looked at the effects of antibiotic administration routes on the level of AMR observed in our patient sample. We saw that current approaches to limit selection for AMR in the gut still resulted in clinically significant and concerning increases in AMR. Furthermore, this chapter allowed greater understanding of contributors to increased AMR in patients. AMR increases are not fully explained by exposure/colonization in hospital settings, but also by evolution of AMR originating from non-resistant bacteria in the gut. Additionally, analysis of these bacteria will inform expected AMR evolutionary trajectories and help us plan against them. During analysis of patient data, we also came across evolution of a less understood resistance phenotype, hetero-resistance, to a very important antibiotic, colistin. We investigated a commonly prescribed antifungal, fluconazole, for its ability to promote this resistance phenotype; however, it appeared that fluconazole did not promote this phenotype. Ultimately, this thesis serves as a valuable reservoir of AMR bacteria for future study and contributes to a greater understanding of AMR development in patients, one day leading to more informed clinical decision making. / Thesis / Master of Science (MSc)

Antimicrobial Resistance

Multi-Drug Resistance

Resistance Evolution

Identification and analysis of Rob, a transcriptional regulator from Serratia marcescens

Nasiri, Jalil

02 February 2011

Serratia marcescens, a member of Enterobacteriaceae family, is a causative agent of nosocomial and opportunistic infections. Numerous reports show that the multidrug resistance among S. marcescens is growing. This organism has high-level intrinsic resistance to a variety of antimicrobial agents, which makes the treatment of infections caused by this bacterium very difficult. The major mechanism for antibiotic resistance, especially to fluoroquinolones, in Gram-negative organisms is the active efflux of the antibiotic molecule mediated by efflux pumps belonging to the Resistance-Nodulation-Cell Division (RND) family. It was previously shown that the SdeAB and SdeXY multidrug efflux pumps are important for conferring the intrinsic drug resistance in S.marcescens. In Escherichia coli, the up-regulation of transcriptional activators, such as MarA, SoxS and Rob, affect transcription of acrAB, tolC and micF. Over-expression of Rob results in increased expression of the E. coli AcrAB-TolC efflux pump and decreases outer membrane permeability through up-regulation of micF, resulting in multidrug, organic solvent and heavy metal resistance. In the present study, we report the identification of a rob gene in S. marcescens which has a 70% identity at the DNA level and 71% identity at the amino acid level to that of E. coli. Moreover, the S. marcescens rob demonstrated similar properties to the E. coli rob including having an effect on expression of outer membrane protein F (OmpF) and over-expression of SdeAB and SdeXY, conferring antibiotic resistance to divergent antibacterial agents and tolerance to organic solvents. We performed rob promoter evaluations using transcriptional fusions to the Green Fluorescence Protein (GFP) in the vector pGlow-TOPO and constructed a rob knock-out using the TargeTron Gene Knockout System. Promoter activity assessment, using the pGlow-TOPO reporter plasmid, showed that rob had higher promoter activity at 37°C than 30°C. In the presence of 2,2’-dipyridyl, rob promoter activity was observed to be slightly increased in the early and mid-log phase by 1.4 and 1.1 fold, respectively. We also showed that sodium decanoate and sodium salicylate can reduce the transcription of rob at 30°C and 37°C. This reduction was observed more potently when rob was exposed to sodium decanoate at 30°C. Minimum inhibitory concentration (MIC) for various antibiotics of the S. marcescens rob knock-out demonstrated a decrease in susceptibility to nalidixic acid, tetracycline, chloramphenicol, ciprofloxacin, norfloxacin, and ofloxacin. Over-expression of rob resulted in an increased resistance by 4, 2, and 2-fold to nalidixic acid, tetracycline and chloramphenicol, respectively. In addition, rob over-production displayed 8, 4, and 4-fold increase in resistance to ciprofloxacin, norfloxacin, ofloxacin, respectively. To discover the role of rob in the efflux mechanism, we performed ethidium bromide accumulation assays on over-expressing and knock-out strains. Organic solvent tolerance assays were carried out using n-hexane to determine if rob is involved in expression of efflux pumps. We found the rob null mutant to be sensitive to n-hexane while the over-expression of rob resulted in resistance to n-hexane. RT-PCR of the rob knock-out strain showed a decrease in expression of micF, ompC, sdeXY, sdeAB and tolC, respectively, and an increase in the expression of ompF. To conclude, we identified a rob homolog in S. marcescens which contributes to resistance to multiple antibiotics and tolerance to organic solvent.

Identification and analysis of Rob, a transcriptional regulator from Serratia marcescens

Nasiri, Jalil

02 February 2011

Serratia marcescens, a member of Enterobacteriaceae family, is a causative agent of nosocomial and opportunistic infections. Numerous reports show that the multidrug resistance among S. marcescens is growing. This organism has high-level intrinsic resistance to a variety of antimicrobial agents, which makes the treatment of infections caused by this bacterium very difficult. The major mechanism for antibiotic resistance, especially to fluoroquinolones, in Gram-negative organisms is the active efflux of the antibiotic molecule mediated by efflux pumps belonging to the Resistance-Nodulation-Cell Division (RND) family. It was previously shown that the SdeAB and SdeXY multidrug efflux pumps are important for conferring the intrinsic drug resistance in S.marcescens. In Escherichia coli, the up-regulation of transcriptional activators, such as MarA, SoxS and Rob, affect transcription of acrAB, tolC and micF. Over-expression of Rob results in increased expression of the E. coli AcrAB-TolC efflux pump and decreases outer membrane permeability through up-regulation of micF, resulting in multidrug, organic solvent and heavy metal resistance. In the present study, we report the identification of a rob gene in S. marcescens which has a 70% identity at the DNA level and 71% identity at the amino acid level to that of E. coli. Moreover, the S. marcescens rob demonstrated similar properties to the E. coli rob including having an effect on expression of outer membrane protein F (OmpF) and over-expression of SdeAB and SdeXY, conferring antibiotic resistance to divergent antibacterial agents and tolerance to organic solvents. We performed rob promoter evaluations using transcriptional fusions to the Green Fluorescence Protein (GFP) in the vector pGlow-TOPO and constructed a rob knock-out using the TargeTron Gene Knockout System. Promoter activity assessment, using the pGlow-TOPO reporter plasmid, showed that rob had higher promoter activity at 37°C than 30°C. In the presence of 2,2’-dipyridyl, rob promoter activity was observed to be slightly increased in the early and mid-log phase by 1.4 and 1.1 fold, respectively. We also showed that sodium decanoate and sodium salicylate can reduce the transcription of rob at 30°C and 37°C. This reduction was observed more potently when rob was exposed to sodium decanoate at 30°C. Minimum inhibitory concentration (MIC) for various antibiotics of the S. marcescens rob knock-out demonstrated a decrease in susceptibility to nalidixic acid, tetracycline, chloramphenicol, ciprofloxacin, norfloxacin, and ofloxacin. Over-expression of rob resulted in an increased resistance by 4, 2, and 2-fold to nalidixic acid, tetracycline and chloramphenicol, respectively. In addition, rob over-production displayed 8, 4, and 4-fold increase in resistance to ciprofloxacin, norfloxacin, ofloxacin, respectively. To discover the role of rob in the efflux mechanism, we performed ethidium bromide accumulation assays on over-expressing and knock-out strains. Organic solvent tolerance assays were carried out using n-hexane to determine if rob is involved in expression of efflux pumps. We found the rob null mutant to be sensitive to n-hexane while the over-expression of rob resulted in resistance to n-hexane. RT-PCR of the rob knock-out strain showed a decrease in expression of micF, ompC, sdeXY, sdeAB and tolC, respectively, and an increase in the expression of ompF. To conclude, we identified a rob homolog in S. marcescens which contributes to resistance to multiple antibiotics and tolerance to organic solvent.

Investigating permeation of anti-mycobacterial agents in Mycobacterium tuberculosis and M. tuberculosis-infected macrophages in vitro as a model for early stage tuberculosis drug discovery

Mabhula, Amanda N

13 August 2021

Tuberculosis (TB) is the leading cause of death due to a single infectious disease and remains a major threat to global public health. The increasing emergence of multi-drug resistance to current anti-TB drugs, exacerbated by the long treatment duration, highlights the need for new effective treatments or strategies to shorten the treatment duration, improve patient adherence and curb the alarming rates of resistance. A key challenge to current strategies employed in the development of anti-TB drugs is the complexity in TB disease pathology which presents as a wide spectrum of lesions in patients presenting with the disease. These lesions occur at different anatomical loci in the same individual and at different stages as the disease progresses. In addition, the interaction between the causative agent, Mycobacterium tuberculosis, and its obligate human host induces physiologic and metabolic changes in the infecting bacillus that are specific to each lesion compartment, and dynamic. This is likely to influence M. tuberculosis susceptibility to antibiotic treatment and, consequently, affect treatment duration and possibly the development of drug resistance. A major limitation in current strategies to address this problem is translation of in vitro compound potency to in vivo efficacy. To reach the target site, a drug must first distribute and accumulate in the lesion microenvironments where bacteria reside: the macrophage host cell and the caseum. This thesis focused on the development of an in vitro infection model that could be used to predict drug penetration into M. tuberculosis-infected macrophages. Of particular interest was the extent to which host intracellular drug concentrations translate into effective antimycobacterial activity. To this end, the thesis comprised three key aspects: (i) characterization of physicochemical properties, antimycobacterial activities and M. tuberculosis-mediated metabolism of selected antiTB compounds; (ii) determination of intracellular drug permeation in resting, activated and foamy macrophages; and (iii) determination of the correlation (or not) between intracellular drug concentration and effective M. tuberculosis growth inhibition. The highly lipophilic natural product, fusidic acid (FA), its known human metabolite, 3-ketofusidic (3-ketoFA or GKFA37), and two C-3 alkyl esters (GKFA16 and GKFA17) as FA prodrugs were utilized in the study. In addition, another chemical class, the less lipophilic benzoxazole-based oxime derivatives were also investigated. Moxifloxacin (MXF), levofloxacin (LVF), bedaquiline (BDQ), rifampicin (RIF) and clofazimine (CFZ) were included for reference as known anti-TB drugs with varying lipophilicities. In chapter 2, FA and derivatives showed potent antimycobacterial activity (~1 µM) with selectivity indices (SI) >20 against the THP-1 macrophage cell line. Predicted artificial membrane permeability assay (PAMPA) results suggested that FA and derivatives would readily permeate the cell membrane. M. tuberculosis metabolized the C-3 alkyl-ester prodrug GKFA17 to form both FA and 3-ketoFA, with complete hydrolysis of the prodrug. FA was metabolized to 3-ketoFA, but the low levels of the metabolite suggested that another unidentified metabolite, presumed to be 3-epifusidic acid (3-epiFA), was formed. In vitro assays revealed that the potent benzoxazole-based oxime carbamates (PMN1-201, PMN1-136 and PMN2-09) were rapidly hydrolyzed by M. tuberculosis and were also susceptible to spontaneous degradation in media, forming the poorly active corresponding free oximes (PMN1-199, PMN1-135 and PMN1-157). In chapter 3, the in vitro macrophage drug uptake assay showed that FA C-3 alkyl prodrugs, GKFA16 and GKFA17, accumulated in significantly higher amounts in resting macrophages in comparison to FA and GKFA37. Accumulation of MXF was comparable to the least accumulated FA derivative, GKFA37, and showed steady state intracellular concentrations over a 6-day period. While GKFA16 and GKFA17 showed continued increasing accumulation, intracellular concentrations of FA and GKFA37 decreased after 48 hours, suggesting a likely susceptibility to macrophage efflux. In infected macrophages, the presence of intracellular bacteria or increasing bacterial burden did not affect the host cell ability to accumulate the drugs. FA and derivatives exhibited bacteriostatic inhibition of intracellular mycobacterial growth. MXF showed a potent bactericidal effect, reducing intracellular bacterial counts significantly at 10x MIC, with complete sterilization at 50x MIC even though MXF accumulation was significantly less than that of FA alkyl esters. These results suggested that both the inherent activity of a compound and ability to accumulate within host cells drive cellular efficacy. Given that the C-3 alkyl ester prodrugs accumulated at significantly higher concentrations than FA and GKFA37, this demonstrates the limitations of this assay in ascertaining the impact of intracellular concentration on drug efficacy for bacteriostatic drugs while highlighting its ability to correlate drug penetration and intracellular activity for cidal drugs. The prodrug GKFA17 was shown to undergo metabolism in resting host cells and during infection to form FA and then 3-ketoFA. Therefore, the prodrug strategy could be used to increase intracellular exposure of FA as GKFA17 showed superior macrophage accumulation. Benzoxazole-based oxime carbamates and their corresponding free oximes failed to accumulate in host macrophages and this was corroborated by their failure to control host cell bacterial growth despite the potent in vitro activity against M. tuberculosis of the carbamates, suggesting that they are poorly permeable. Chapter 4 investigated drug permeation in different macrophage phenotypes known to exist in the granuloma during TB disease, including foamy and activated macrophages. The activation state of the host cell did not affect the ability to accumulate anti-TB drugs such as RIF and BDQ. However, FA and its prodrug GKFA17 were significantly reduced in M1 activated macrophages. Despite the significantly reduced intracellular concentration, activated macrophages treated with FA and derivatives showed superior intracellular M. tuberculosis growth inhibition, suggesting that macrophage activation potentiates the activity of these compounds. In order to assess the effect of foamy macrophage lipid bodies (LBs) on drug uptake and intracellular localization, oleic acid-induced foamy macrophages were treated with selected antiTB drugs and experimental compounds. FA and derivatives showed early increased accumulation in foamy cells compared to resting macrophages, while MXF, BDQ and RIF levels were not significantly changed. Intracellular:extracellular (I/E) ratios increased with increase in lipophilicity, with FA C-3 alkyl prodrugs exhibiting the highest I/E ratios of >100. Despite exhibiting increased foamy macrophage concentrations, FA and derivatives exhibited a similar reduction (bacteriostatic) in bacterial counts in both resting and foamy macrophages. The intracellular activity of RIF was also not affected by presence of LBsin foamy macrophages. BDQ, LVF and MXF, however, showed reduced intracellular efficacy against M. tuberculosis in foamy macrophages compared to resting macrophages, suggesting a role for LBs to impact intracellular drug distribution. In conclusion, this thesis demonstrates the potential utility in combining advanced analytical methods and an in vitro infection model to determine cellular drug permeation profiles that might be applied to prioritize compounds and combinations optimized for distribution to target bacterial populations. This will facilitate well-informed decision-making processes in progression of lead compounds in pre-clinical development and, therefore, may offer the potential to reduce high rates of attrition of compounds which enter clinical phase of development.

Tuberculosis

TB

multi-drug resistance

anti-TB drugs

Impact d’une politique proactive de surveillance et de gestion des risques infectieux dans un centre hospitalo-universitaire parisien sur la diffusion des Bactéries Multi-Résistantes aux antibiotiques / Impact of a proactive surveillance and infectious risk management policy in a Parisian teachting hospital on the Multi-Resistant bacteria spread

Grohs, Patrick

20 December 2017

Cette thèse recouvre une période de 15 ans de lutte contre la diffusion hospitalière des bactéries multi-résistantes aux antibiotiques (BMR) au sein d’un CHU parisien pilote. Elle intègre plusieurs études axées sur les outils informatiques de surveillance, la maîtrise de la transmission croisée, et le bon usage des antibiotiques. La configuration d'une base de données dédiée, concentrant l'ensemble des données de la résistance, doit intégrer des critères de requêtes épidémiologique précis, normalisés, et reproductibles. Des variations significatives du taux de Staphylococcus aureus résistant à la méticilline (SARM) ont été observées en fonction de la méthode d'élimination des doublons utilisée (de 27,6% à 33,8%), et l’extrapolation des résultats annuels à partir de données colligées sur des unités de temps plus courtes, mésestime la valeur annuelle de l’incidence du SARM (de -42% à +30%). Ces variations peuvent influer sur l'interprétation des indicateurs relatifs au SARM. L'alerte électronique BMR, en avertissant les soignants de la réadmission d'un patient porteur au sein de leur unité, a permis d'optimiser la compliance aux mesures de précautions contact complémentaires (15% avant vs 90,2% après), et de participer à la diminution de l’incidence du SARM (1,07 en 2002 vs 0,37 en 2012). Elle a également mis en évidence la forte pression de colonisation due aux patients SARM réadmis, 46% des patients porteurs étant réadmis au moins une fois dont les 2/3, moins de trois mois après leur sortie. En réanimation, 1/5 des patients sont porteurs d’Entérobactéries productrices de béta-lactamase à spectre étendu (EBLSE) et/ou hyperproductrices de céphalosporinase (HP-CASE), les taux de portage à l’admission étant respectivement de 79,2% et 48,1% rapportés à l’ensemble des patients porteurs. Aucune stratégie de dépistage n’assure une identification de 100% des patients porteurs, la discontinuité de portage au cours du séjour concernant la majorité des patients. Le remplacement de la ceftriaxone par le cefotaxime a permis de ralentir la progression de l'incidence des HP-CASE. Enfin, l’optimisation du dépistage des EBLSE par l'évaluation puis l'utilisation de robots et de milieux de culture dédiés, a permis de gérer l’inflation des échantillons de dépistage / This work describes 15 years of fight against the spread of multi-drug resistant bacteria (MRB) in a tertiary care hospital, and includes several published studies focused on monitoring systems, cross-transmission control, and antibiotics policy. Data processing plays a crucial role in monitoring MRB. The configuration of a dedicated database, concentrating all resistance data, has to include accurate, standardized, and reproducible epidemiological settings. Significant changes in the methicillin-resistant staphylococcus aureus (MRSA) rate were observed, according to the method used to remove duplicates (27.6% to 33.8%), and the extrapolation of annual results from data collected from shorter period length, underestimates the annual value of MRSA incidence (from -42% to + 30%). These variations may affect the interpretation of MRSA official indicators. The MRB electronic alert, used to warn the staff of the readmission of a previously known colonized patient, conducted to increase the compliance for implementation of infection control measures (15% before vs 90.2% after), and participated in reducing the MRSA incidence (1.07 in 2002 vs. 0.37 in 2012). It also highlighted the strong colonization pressure due to readmitted MRSA colonized patients, since 46% of them were readmitted at least once, readmissions occurring less than three months after discharge in 2/3 cases. In intensive care units, 1/5 patient are colonized by Enterobacteriaceae producing broad spectrum beta-lactamase (ESBL) and/or high level cephalosporinase (HL-CASE), rates at admission being respectively 79.2% and 48.1% when considering all colonized patients. No screening strategy is able to detect 100% of colonization situations, the discontinuity of colonization during the hospital stay concerning a majority of patients. A significant inflexion in the slope in the HL-CASE incidence curve occurred after the substitution of ceftriaxone by cefotaxime. Finally, the optimization of ESBL screening by the assessment and then the use of a robot and dedicated culture media, allowed managing the increased number of screening specimens

Antibio-Résistance

Informatique

Hopital

Dépistage

Sarm

Blse

Multi-Drug resistance

Data management

Hospital

Screening

Mrsa

Esbl

Treatment strategies to reverse efflux transporter-mediated resistance to Tyrosine kinase inhibitors

D'Cunha, Ronilda Raymond

01 December 2018

Multidrug resistance (MDR), a phenomenon in which tumors that were initially sensitive, recur and start showing resistance not only to the initial chemotherapeutic agent but also to various anticancer drugs that are structurally and functionally different from the initial drug, constitutes one of the main reasons for the failure of chemotherapy. An important mechanism of MDR is the enhanced cellular efflux of anticancer agents due to an overexpression of ATP-binding cassette (ABC) transporters (i.e. efflux transporters), especially P-glycoprotein (Pgp), Multidrug Resistance-associated Protein 1 (MRP1) and Breast Cancer Resistance Protein (BCRP), in cancer cells. In order to reverse this resistance, there has been a lot of emphasis on the development of Pgp, MRP1 and BCRP inhibitors. Although this search has been ongoing for three decades, there are still no clinically available efflux transporter modulators. Tyrosine kinase inhibitors (TKIs) are a novel, rapidly growing class of anticancer agents that have a target-based mechanism of action, and their use transformed cancer chemotherapy due to higher specificity and enhanced safety profiles compared to conventional chemotherapeutic agents. Despite their tremendous success in treating various types of tumors, patients develop resistance to TKIs over time. Most of the FDA- approved TKIs are substrates of Pgp and/or BCRP, and as a result, these efflux transporters are also an important cause of conferred resistance against TKIs in cancer cells. Additionally, none of the 31 approved TKIs have an indication for use in brain tumors and interestingly, this may also due to the presence of Pgp and BCRP at the blood-brain barrier (BBB) and in the tumor cells, which prevent the TKI from crossing the BBB and reaching its target tumor site. Since Pgp- and BCRP- mediated TKI efflux has been shown to be involved in TKI resistance, the inhibition of these transporters could represent a potential TKI resistance reversal strategy. Over the last three decades, a large number of Pgp and/or BCRP inhibitors have been identified, but none of them have successfully made it to the clinic. It was observed that most drugs identified as inhibitors were either unable to achieve Pgp and BCRP inhibitory concentrations in-vivo without imparting severe toxicity, or did not possess adequate bioavailability and tissue distribution profiles in order to reach the tumor site. From these identified candidate inhibitors, after much thought and consideration, we chose to investigate TKIs and methylated flavones as modulators of efflux transporter-mediated TKI resistance. The overall goal of this project was to investigate the promising chemosensitizing potential of TKIs and methylated flavones in efflux transporter-mediated TKI resistance, both in-vitro and in-vivo. To identify potent efflux transporter inhibitor TKIs, we evaluated the effect of various TKIs on the accumulation of afatinib, the model TKI substrate, in Pgp- and BCRP- overexpressing cell lines. Afatinib was chosen as the model TKI substrate for our study because it undergoes very minimal metabolism in several species. Afatinib is a substrate of both Pgp and BCRP, but is not a substrate of uptake transporters. Therefore, it was anticipated that an in-vivo efflux transporter-mediated interaction with afatinib would most likely not be confounded or masked by other factors influencing its disposition. From the in-vitro cell uptake studies, we found that nilotinib is a potent inhibitor of both Pgp and BCRP, and it reversed Pgp- and BCRP- mediated afatinib efflux. Subsequently, an in-vivo study was carried out in mice to investigate the interaction between afatinib and nilotinib; and also the impact of nilotinib on the pharmacokinetics and tissue distribution of afatinib. Afatinib exposure in the plasma and in most tissues, namely liver, lung, kidney, heart, muscle, fat, and skin, was found to be significantly increased when nilotinib was coadministered with afatinib. Further, the nilotinib concentrations in most mice tissues was above that needed for Pgp and BCRP inhibition. These results showed that nilotinib could be a potent chemosensitizing agent for Pgp- and BCRP- mediated TKI resistance. Additionally, a significant increase in afatinib brain exposure was observed in the mice which were administered afatinib in combination with nilotinib. This is an interesting and important finding that could potentially be very useful in the treatment of primary and metastasized brain tumors. We also developed a physiologically based pharmacokinetic model of afatinib to characterize its tissue disposition in mice organs, and this model was then scaled up to humans. The developed model accurately predicted afatinib plasma exposure in healthy volunteers and patients with solid malignant tumors, renal impairment, and hepatic impairment. To investigate the chemosensitizing potential of methylated flavones in efflux transporter-mediated TKI resistance, the Bcrp1 inhibitory effect of 5,7-DMF and its effect on sorafenib accumulation was evaluated in-vitro. 5,7- DMF was found to be a potent inhibitor of Bcrp1 and consequently, its impact on the pharmacokinetics and tissue distribution of sorafenib was evaluated in mice. Results showed that co-administration with 5,7-DMF led to significantly greater sorafenib exposure in plasma and in most tissues collected. This indicated that 5,7-DMF may represent a promising chemosensitizing agent for Bcrp1-mediated TKI resistance due to its low toxicity and potent Bcrp1 inhibition. Our results may have important clinical implications as TKIs are currently the most widely used anticancer agents. 5,7-DMF may show great potential in reversing MDR in tumors expressing BCRP. On the other hand, TKI-TKI combination therapy, especially with nilotinib as the perpetrator, is an attractive strategy to combat both Pgp- and BCRP-mediated TKI resistance. Additionally, since nilotinib has a wide volume of distribution and can reach various tissues at concentrations sufficient enough to inhibit Pgp and BCRP; it could potentially be used as a chemosensitizer in the treatment of numerous types of cancers. Furthermore, its chemosensitizing potential could particularly be useful in the treatment of primary and metastatic brain tumors. Further studies are warranted to assess the chemosensitizing effect of nilotinib in tumor xenograft models.

drug-drug interaction

Efflux transporter inhibitors

Multi-drug resistance

pharmacokinetics

Tyrosine Kinase Inhibitors

Development of block copolymer based nanocarriers for the solubilization and delivery of valspodar

Binkhathlan, Ziyad

Unknown Date

No description available.

block copolymer

polymeric micelles

polymeric vesicles

multi-drug resistance

cancer

P-glycoprotein

valspodar

pharmacokinetics