Your search keyword '"Michael Neely"' showing total 5 results

1. In-vitro and in-vivo assessment of nirmatrelvir penetration into CSF, central nervous system cells, tissues, and peripheral blood mononuclear cells

Author

Sean N. Avedissian, Johid R. Malik, Anthony T. Podany, Michael Neely, Nathaniel J. Rhodes, Kimberly K. Scarsi, Marc H. Scheetz, Michael J. Duryee, Ukamaka O. Modebelu, Timothy M. Mykris, Lee C. Winchester, Siddappa N. Byrareddy, and Courtney V. Fletcher

Subjects

Nirmatrelvir/ritonavir, Blood–brain-barrier, Central nervous system, Medicine, Science

Abstract

Abstract Three years after SARS-CoV-2 emerged as a global infectious threat, the virus has become endemic. The neurological complications such as depression, anxiety, and other CNS complications after COVID-19 disease are increasing. The brain, and CSF have been shown as viral reservoirs for SARS-CoV-2, yielding a potential hypothesis for CNS effects. Thus, we investigated the CNS pharmacology of orally dosed nirmatrelvir/ritonavir (NMR/RTV). Using both an in vitro and an in vivo rodent model, we investigated CNS penetration and potential pharmacodynamic activity of NMR. Through pharmacokinetic modeling, we estimated the median CSF penetration of NMR to be low at 18.11% of plasma with very low accumulation in rodent brain tissue. Based on the multiples of the 90% maximal effective concentration (EC90) for SARS-CoV-2, NMR concentrations in the CSF and brain do not achieve an exposure level similar to that of plasma. A median of only 16% of all the predicted CSF concentrations in rats were > 3xEC90 (unadjusted for protein binding). This may have implications for viral persistence and neurologic post-acute sequelae of COVID-19 if increased NMR penetration in the CNS leads to decreased CNS viral loads and decreased CNS inflammation.

Published

2024

2. 30 Determining a potential alternative empirical antibiotic regimen for the treatment of neonatal sepsis in low- and middle-income settings using pre-clinical in vitro techniques

Author

Christopher Darlow, Nicola Farrington, Laura McEntee, Adam Johnson, Jennifer Unsworth, Ana Jimenez-Valverde, Bhavana Jagota, Fernando Docobo-Perez, Ruwanthi Kolamunnage-Dona, Renata de Costa, Sally Ellis, François Franceschi, Mike Sharland, Michael Neely, Laura Piddock, Shampa Das, and William Hope

Subjects

Infectious and parasitic diseases, RC109-216

Published

2022

3. Tacrolimus Updated Guidelines through popPK Modeling: How to Benefit More from CYP3A Pre-emptive Genotyping Prior to Kidney Transplantation

Author

Jean-Baptiste Woillard, Michel Mourad, Michael Neely, Arnaud Capron, Ron H. van Schaik, Teun van Gelder, Nuria Lloberas, Dennis A. Hesselink, Pierre Marquet, Vincent Haufroid, and Laure Elens

Subjects

tacrolimus, kidney transplantation, CYP3A, single nucleotide polymorphisms, population pharmacokinetics, dosage recommendations, Therapeutics. Pharmacology, RM1-950

Abstract

Tacrolimus (Tac) is a profoundly effective immunosuppressant that reduces the risk of rejection after solid organ transplantation. However, its use is hampered by its narrow therapeutic window along with its highly variable pharmacological (pharmacokinetic [PK] and pharmacodynamic [PD]) profile. Part of this variability is explained by genetic polymorphisms affecting the metabolic pathway. The integration of CYP3A4 and CY3A5 genotype in tacrolimus population-based PK (PopPK) modeling approaches has been proven to accurately predict the dose requirement to reach the therapeutic window. The objective of the present study was to develop an accurate PopPK model in a cohort of 59 kidney transplant patients to deliver this information to clinicians in a clear and actionable manner. We conducted a non-parametric non-linear effects PopPK modeling analysis in Pmetrics®. Patients were genotyped for the CYP3A4∗22 and CYP3A5∗3 alleles and were classified into 3 different categories [poor-metabolizers (PM), Intermediate-metabolizers (IM) or extensive-metabolizers (EM)]. A one-compartment model with double gamma absorption route described very accurately the tacrolimus PK. In covariate analysis, only CYP3A genotype was retained in the final model (Δ-2LL = -73). Our model estimated that tacrolimus concentrations were 33% IC95%[20–26%], 41% IC95%[36–45%] lower in CYP3A IM and EM when compared to PM, respectively. Virtually, we proved that defining different starting doses for PM, IM and EM would be beneficial by ensuring better probability of target concentrations attainment allowing us to define new dosage recommendations according to patient CYP3A genetic profile.

Published

2017

4. Managing treatment-experienced pediatric and adolescent HIV patients: role of darunavir

Author

Michael Neely and Andrea Kovacs

Subjects

Therapeutics. Pharmacology, RM1-950

Abstract

Michael Neely, Andrea KovacsUniversity of Southern California Keck School of Medicine, Department of Pediatrics, Division of infectious Diseases, Los Angeles, CA, USAAbstract: Darunavir is currently the most recently approved HIV-1 protease inhibitor. It is approved for twice-daily dosing with ritonavir in treatment-experienced patients as young as 6 years of age and is available in numerous pill strengths. Emergence of darunavir-specific mutations is generally slow; therefore it can retain activity against viral strains that are resistant to other protease inhibitors, including tipranavir. Darunavir pharmacokinetics, clinical efficacy, resistance mutations and pharmacodynamics, and adverse effects are reviewed here. Substantial data support its use as a potent, well-tolerated option for salvage therapy in highly treatment experienced children and adolescents.Keywords: darunavir, protease inhibitors, treatment, child, adolescent

Published

2009

5. Analysis of combination drug therapy to develop regimens with shortened duration of treatment for tuberculosis.

Author

George L Drusano, Michael Neely, Michael Van Guilder, Alan Schumitzky, David Brown, Steven Fikes, Charles Peloquin, and Arnold Louie

Subjects

Medicine, Science

Abstract

RationaleTuberculosis remains a worldwide problem, particularly with the advent of multi-drug resistance. Shortening therapy duration for Mycobacterium tuberculosis is a major goal, requiring generation of optimal kill rate and resistance-suppression. Combination therapy is required to attain the goal of shorter therapy.ObjectivesOur objective was to identify a method for identifying optimal combination chemotherapy. We developed a mathematical model for attaining this end. This is accomplished by identifying drug effect interaction (synergy, additivity, antagonism) for susceptible organisms and subpopulations resistant to each drug in the combination.MethodsWe studied the combination of linezolid plus rifampin in our hollow fiber infection model. We generated a fully parametric drug effect interaction mathematical model. The results were subjected to Monte Carlo simulation to extend the findings to a population of patients by accounting for between-patient variability in drug pharmacokinetics.ResultsAll monotherapy allowed emergence of resistance over the first two weeks of the experiment. In combination, the interaction was additive for each population (susceptible and resistant). For a 600 mg/600 mg daily regimen of linezolid plus rifampin, we demonstrated that >50% of simulated subjects had eradicated the susceptible population by day 27 with the remaining organisms resistant to one or the other drug. Only 4% of patients had complete organism eradication by experiment end.DiscussionThese data strongly suggest that in order to achieve the goal of shortening therapy, the original regimen may need to be changed at one month to a regimen of two completely new agents with resistance mechanisms independent of the initial regimen. This hypothesis which arose from the analysis is immediately testable in a clinical trial.

Published

2014