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Literature DB >> 32066976

Dynamic imaging in patients with tuberculosis reveals heterogeneous drug exposures in pulmonary lesions.

Alvaro A Ordonez^1,2,3, Hechuan Wang⁴, Gesham Magombedze⁵, Camilo A Ruiz-Bedoya^1,2,3, Shashikant Srivastava⁵, Allen Chen^1,6, Elizabeth W Tucker^1,2,7, Michael E Urbanowski^2,8, Lisa Pieterse^1,2,7, E Fabian Cardozo⁹, Martin A Lodge⁶, Maunank R Shah^2,8, Daniel P Holt⁶, William B Mathews⁶, Robert F Dannals⁶, Jogarao V S Gobburu⁴, Charles A Peloquin¹⁰, Steven P Rowe⁶, Tawanda Gumbo⁵, Vijay D Ivaturi⁴, Sanjay K Jain^11,12,13,14.

Abstract

Tuberculosis (TB) is the leading cause of death from a single infectious agent, requiring at least 6 months of multidrug treatment to achieve cure1. However, the lack of reliable data on antimicrobial pharmacokinetics (PK) at infection sites hinders efforts to optimize antimicrobial dosing and shorten TB treatments2. In this study, we applied a new tool to perform unbiased, noninvasive and multicompartment measurements of antimicrobial concentration-time profiles in humans3. Newly identified patients with rifampin-susceptible pulmonary TB were enrolled in a first-in-human study4 using dynamic [11C]rifampin (administered as a microdose) positron emission tomography (PET) and computed tomography (CT). [11C]rifampin PET-CT was safe and demonstrated spatially compartmentalized rifampin exposures in pathologically distinct TB lesions within the same patients, with low cavity wall rifampin exposures. Repeat PET-CT measurements demonstrated independent temporal evolution of rifampin exposure trajectories in different lesions within the same patients. Similar findings were recapitulated by PET-CT in experimentally infected rabbits with cavitary TB and confirmed using postmortem mass spectrometry. Integrated modeling of the PET-captured concentration-time profiles in hollow-fiber bacterial kill curve experiments provided estimates on the rifampin dosing required to achieve cure in 4 months. These data, capturing the spatial and temporal heterogeneity of intralesional drug PK, have major implications for antimicrobial drug development.

Entities: Chemical Disease Gene Species

Mesh：

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Year: 2020 PMID： 32066976 PMCID： PMC7160048 DOI： 10.1038/s41591-020-0770-2

Source DB: PubMed Journal: Nat Med ISSN： 1078-8956 Impact factor: 53.440

42 in total

1. Noninvasive ¹¹C-rifampin positron emission tomography reveals drug biodistribution in tuberculous meningitis.

Authors: Elizabeth W Tucker; Beatriz Guglieri-Lopez; Alvaro A Ordonez; Brittaney Ritchie; Mariah H Klunk; Richa Sharma; Yong S Chang; Julian Sanchez-Bautista; Sarah Frey; Martin A Lodge; Steven P Rowe; Daniel P Holt; Jogarao V S Gobburu; Charles A Peloquin; William B Mathews; Robert F Dannals; Carlos A Pardo; Sujatha Kannan; Vijay D Ivaturi; Sanjay K Jain
Journal: Sci Transl Med Date: 2018-12-05 Impact factor: 17.956

2. Early bactericidal activity of high-dose rifampin in patients with pulmonary tuberculosis evidenced by positive sputum smears.

Authors: A H Diacon; R F Patientia; A Venter; P D van Helden; P J Smith; H McIlleron; J S Maritz; P R Donald
Journal: Antimicrob Agents Chemother Date: 2007-05-21 Impact factor: 5.191

3. Impact of nonlinear interactions of pharmacokinetics and MICs on sputum bacillary kill rates as a marker of sterilizing effect in tuberculosis.

Authors: Emmanuel Chigutsa; Jotam G Pasipanodya; Marianne E Visser; Paul D van Helden; Peter J Smith; Frederick A Sirgel; Tawanda Gumbo; Helen McIlleron
Journal: Antimicrob Agents Chemother Date: 2014-10-13 Impact factor: 5.191

4. Serum drug concentrations predictive of pulmonary tuberculosis outcomes.

Authors: Jotam G Pasipanodya; Helen McIlleron; André Burger; Peter A Wash; Peter Smith; Tawanda Gumbo
Journal: J Infect Dis Date: 2013-07-29 Impact factor: 5.226

5. Determination of [11C]rifampin pharmacokinetics within Mycobacterium tuberculosis-infected mice by using dynamic positron emission tomography bioimaging.

Authors: Vincent P DeMarco; Alvaro A Ordonez; Mariah Klunk; Brendan Prideaux; Hui Wang; Zhang Zhuo; Peter J Tonge; Robert F Dannals; Daniel P Holt; Carlton K K Lee; Edward A Weinstein; Véronique Dartois; Kelly E Dooley; Sanjay K Jain
Journal: Antimicrob Agents Chemother Date: 2015-07-13 Impact factor: 5.191

6. Evolution of rifampicin treatment for tuberculosis.

Authors: Melanie Grobbelaar; Gail E Louw; Samantha L Sampson; Paul D van Helden; Peter R Donald; Robin M Warren
Journal: Infect Genet Evol Date: 2019-06-24 Impact factor: 3.342

Review 7. Understanding pharmacokinetics to improve tuberculosis treatment outcome.

Authors: Jonathan Reynolds; Scott K Heysell
Journal: Expert Opin Drug Metab Toxicol Date: 2014-03-06 Impact factor: 4.481

8. Greater Early Bactericidal Activity at Higher Rifampicin Doses Revealed by Modeling and Clinical Trial Simulations.

Authors: Robin J Svensson; Elin M Svensson; Rob E Aarnoutse; Andreas H Diacon; Rodney Dawson; Stephen H Gillespie; Mischka Moodley; Martin J Boeree; Ulrika S H Simonsson
Journal: J Infect Dis Date: 2018-08-14 Impact factor: 5.226

9. High-dose rifampicin, moxifloxacin, and SQ109 for treating tuberculosis: a multi-arm, multi-stage randomised controlled trial.

Authors: Martin J Boeree; Norbert Heinrich; Rob Aarnoutse; Andreas H Diacon; Rodney Dawson; Sunita Rehal; Gibson S Kibiki; Gavin Churchyard; Ian Sanne; Nyanda E Ntinginya; Lilian T Minja; Robert D Hunt; Salome Charalambous; Madeleine Hanekom; Hadija H Semvua; Stellah G Mpagama; Christina Manyama; Bariki Mtafya; Klaus Reither; Robert S Wallis; Amour Venter; Kim Narunsky; Anka Mekota; Sonja Henne; Angela Colbers; Georgette Plemper van Balen; Stephen H Gillespie; Patrick P J Phillips; Michael Hoelscher
Journal: Lancet Infect Dis Date: 2016-10-26 Impact factor: 25.071

10. Drug Concentration Thresholds Predictive of Therapy Failure and Death in Children With Tuberculosis: Bread Crumb Trails in Random Forests.

Authors: Soumya Swaminathan; Jotam G Pasipanodya; Geetha Ramachandran; A K Hemanth Kumar; Shashikant Srivastava; Devyani Deshpande; Eric Nuermberger; Tawanda Gumbo
Journal: Clin Infect Dis Date: 2016-11-01 Impact factor: 9.079

29 in total

Review 1. Phase 0/microdosing approaches: time for mainstream application in drug development?

Authors: Tal Burt; Graeme Young; Wooin Lee; Hiroyuki Kusuhara; Oliver Langer; Malcolm Rowland; Yuichi Sugiyama
Journal: Nat Rev Drug Discov Date: 2020-09-08 Impact factor: 84.694

Review 2. Small Molecule Sensors Targeting the Bacterial Cell Wall.

Authors: Matthew F L Parker; Robert R Flavell; Justin M Luu; Oren S Rosenberg; Michael A Ohliger; David M Wilson
Journal: ACS Infect Dis Date: 2020-06-09 Impact factor: 5.084

Review 3. Advanced imaging tools for childhood tuberculosis: potential applications and research needs.

Authors: Sanjay K Jain; Savvas Andronikou; Pierre Goussard; Sameer Antani; David Gomez-Pastrana; Christophe Delacourt; Jeffrey R Starke; Alvaro A Ordonez; Patrick Jean-Philippe; Renee S Browning; Carlos M Perez-Velez
Journal: Lancet Infect Dis Date: 2020-06-23 Impact factor: 25.071

4. Radiosynthesis and Biodistribution of ¹⁸F-Linezolid in Mycobacterium tuberculosis-Infected Mice Using Positron Emission Tomography.

Authors: Filipa Mota; Ravindra Jadhav; Camilo A Ruiz-Bedoya; Alvaro A Ordonez; Mariah H Klunk; Joel S Freundlich; Sanjay K Jain
Journal: ACS Infect Dis Date: 2020-04-09 Impact factor: 5.084

Review 5. Cavitary tuberculosis: the gateway of disease transmission.

Authors: Michael E Urbanowski; Alvaro A Ordonez; Camilo A Ruiz-Bedoya; Sanjay K Jain; William R Bishai
Journal: Lancet Infect Dis Date: 2020-05-05 Impact factor: 25.071

Review 6. Radiotracer Development for Bacterial Imaging.

Authors: Filipa Mota; Alvaro A Ordonez; George Firth; Camilo A Ruiz-Bedoya; Michelle T Ma; Sanjay K Jain
Journal: J Med Chem Date: 2020-02-21 Impact factor: 7.446

7. Imaging Enterobacterales infections in patients using pathogen-specific positron emission tomography.

Authors: Alvaro A Ordonez; Luz M Wintaco; Filipa Mota; Andres F Restrepo; Camilo A Ruiz-Bedoya; Carlos F Reyes; Luis G Uribe; Sudhanshu Abhishek; Franco R D'Alessio; Daniel P Holt; Robert F Dannals; Steven P Rowe; Victor R Castillo; Martin G Pomper; Ulises Granados; Sanjay K Jain
Journal: Sci Transl Med Date: 2021-04-14 Impact factor: 17.956

8. Mycobacterium tuberculosis sterilizing activity of faropenem, pyrazinamide and linezolid combination and failure to shorten the therapy duration.

Authors: Tawanda Gumbo; Carleton M Sherman; Devyani Deshpande; Jan-Willem Alffenaar; Shashikant Srivastava
Journal: Int J Infect Dis Date: 2021-02-05 Impact factor: 3.623

9. Genomic analyses of Mycobacterium tuberculosis from human lung resections reveal a high frequency of polyclonal infections.

Authors: Miguel Moreno-Molina; Natalia Shubladze; Iza Khurtsilava; Zaza Avaliani; Nino Bablishvili; Manuela Torres-Puente; Luis Villamayor; Andrei Gabrielian; Alex Rosenthal; Cristina Vilaplana; Sebastien Gagneux; Russell R Kempker; Sergo Vashakidze; Iñaki Comas
Journal: Nat Commun Date: 2021-05-11 Impact factor: 17.694

10. Application of a plasmin generation assay to define pharmacodynamic effects of tranexamic acid in women undergoing cesarean delivery.

Authors: Adam Miszta; Homa K Ahmadzia; Naomi L C Luban; Shuhui Li; Dong Guo; Lori A Holle; Jeffrey S Berger; Andra H James; Jogarao V S Gobburu; John van den Anker; Bas de Laat; Alisa S Wolberg
Journal: J Thromb Haemost Date: 2020-12-26 Impact factor: 5.824