Characteristics of hepatitis C virus resistance in an international cohort after a decade of direct-acting antivirals.
DAA
DAA, direct-acting antiviral
DCV, daclatasvir
DSV, dasabuvir
GT, genotype
HCV
LDV, ledipasvir
NI, nucleoside
NNI, non-nucleoside
NS5A
NS5AI, NS5A replication complex inhibitor
OR, odds ratio
PI, NS3 protease inhibitor
PIB, pibrentasvir
RAS
RASs, resistance-associated substitutions
SHARED, The Surveillance of Hepatitis C Antiviral Resistance, Epidemiology and methoDologies
SOF, sofosbuvir
SVR, sustained virologic response
VEL, velpatasvir
aOR, adjusted odds ratio
sFC, substitution frequency change
virologic failure
Journal
JHEP reports : innovation in hepatology
ISSN: 2589-5559
Titre abrégé: JHEP Rep
Pays: Netherlands
ID NLM: 101761237
Informations de publication
Date de publication:
May 2022
May 2022
Historique:
received:
02
02
2022
accepted:
05
02
2022
entrez:
18
4
2022
pubmed:
19
4
2022
medline:
19
4
2022
Statut:
epublish
Résumé
Direct-acting antiviral (DAA) regimens provide a cure in >95% of patients with chronic HCV infection. However, in some patients in whom therapy fails, resistance-associated substitutions (RASs) can develop, limiting retreatment options and risking onward resistant virus transmission. In this study, we evaluated RAS prevalence and distribution, including novel NS5A RASs and clinical factors associated with RAS selection, among patients who experienced DAA treatment failure. SHARED is an international consortium of clinicians and scientists studying HCV drug resistance. HCV sequence linked metadata from 3,355 patients were collected from 22 countries. NS3, NS5A, and NS5B RASs in virologic failures, including novel NS5A substitutions, were examined. Associations of clinical and demographic characteristics with RAS selection were investigated. The frequency of RASs increased from its natural prevalence following DAA exposure: 37% to 60% in NS3, 29% to 80% in NS5A, 15% to 22% in NS5B for sofosbuvir, and 24% to 37% in NS5B for dasabuvir. Among 730 virologic failures, most were treated with first-generation DAAs, 94% had drug resistance in ≥1 DAA class: 31% single-class resistance, 42% dual-class resistance (predominantly against protease and NS5A inhibitors), and 21% triple-class resistance. Distinct patterns containing ≥2 highly resistant RASs were common. New potential NS5A RASs and adaptive changes were identified in genotypes 1a, 3, and 4. Following DAA failure, RAS selection was more frequent in older people with cirrhosis and those infected with genotypes 1b and 4. Drug resistance in HCV is frequent after DAA treatment failure. Previously unrecognized substitutions continue to emerge and remain uncharacterized. Although direct-acting antiviral medications effectively cure hepatitis C in most patients, sometimes treatment selects for resistant viruses, causing antiviral drugs to be either ineffective or only partially effective. Multidrug resistance is common in patients for whom DAA treatment fails. Older patients and patients with advanced liver diseases are more likely to select drug-resistant viruses. Collective efforts from international communities and governments are needed to develop an optimal approach to managing drug resistance and preventing the transmission of resistant viruses.
Sections du résumé
Background & Aims
UNASSIGNED
Direct-acting antiviral (DAA) regimens provide a cure in >95% of patients with chronic HCV infection. However, in some patients in whom therapy fails, resistance-associated substitutions (RASs) can develop, limiting retreatment options and risking onward resistant virus transmission. In this study, we evaluated RAS prevalence and distribution, including novel NS5A RASs and clinical factors associated with RAS selection, among patients who experienced DAA treatment failure.
Methods
UNASSIGNED
SHARED is an international consortium of clinicians and scientists studying HCV drug resistance. HCV sequence linked metadata from 3,355 patients were collected from 22 countries. NS3, NS5A, and NS5B RASs in virologic failures, including novel NS5A substitutions, were examined. Associations of clinical and demographic characteristics with RAS selection were investigated.
Results
UNASSIGNED
The frequency of RASs increased from its natural prevalence following DAA exposure: 37% to 60% in NS3, 29% to 80% in NS5A, 15% to 22% in NS5B for sofosbuvir, and 24% to 37% in NS5B for dasabuvir. Among 730 virologic failures, most were treated with first-generation DAAs, 94% had drug resistance in ≥1 DAA class: 31% single-class resistance, 42% dual-class resistance (predominantly against protease and NS5A inhibitors), and 21% triple-class resistance. Distinct patterns containing ≥2 highly resistant RASs were common. New potential NS5A RASs and adaptive changes were identified in genotypes 1a, 3, and 4. Following DAA failure, RAS selection was more frequent in older people with cirrhosis and those infected with genotypes 1b and 4.
Conclusions
UNASSIGNED
Drug resistance in HCV is frequent after DAA treatment failure. Previously unrecognized substitutions continue to emerge and remain uncharacterized.
Lay summary
UNASSIGNED
Although direct-acting antiviral medications effectively cure hepatitis C in most patients, sometimes treatment selects for resistant viruses, causing antiviral drugs to be either ineffective or only partially effective. Multidrug resistance is common in patients for whom DAA treatment fails. Older patients and patients with advanced liver diseases are more likely to select drug-resistant viruses. Collective efforts from international communities and governments are needed to develop an optimal approach to managing drug resistance and preventing the transmission of resistant viruses.
Identifiants
pubmed: 35434589
doi: 10.1016/j.jhepr.2022.100462
pii: S2589-5559(22)00034-9
pmc: PMC9010635
doi:
Types de publication
Journal Article
Langues
eng
Pagination
100462Investigateurs
Marianne Martinello
(M)
Gail Matthews
(G)
Fay Fabián Fernando
(FF)
Juan I Esteban
(JI)
Beat Müllhaupt
(B)
Julian Schulze Zur Wiesch
(JSZ)
Peter Buggisch
(P)
Christoph Neumann-Haefelin
(C)
Thomas Berg
(T)
Christoph P Berg
(CP)
Jörn M Schattenberg
(JM)
Christophe Moreno
(C)
Rudolf Stauber
(R)
Andrew Lloyd
(A)
Gregory Dore
(G)
Tanya Applegate
(T)
Juan Ignacio
(J)
Damir Garcia-Cehic
(D)
Josep Gregori
(J)
Francisco Rodriguez-Frias
(F)
Ariadna Rando
(A)
Yael Gozlan
(Y)
Mario Angelico
(M)
Massimo Andreoni
(M)
Sergio Babudieri
(S)
Ada Bertoli
(A)
Valeria Cento
(V)
Nicola Coppola
(N)
Antonio Craxì
(A)
Stefania Paolucci
(S)
Giustino Parruti
(G)
Caterina Pasquazzi
(C)
Carlo Federico Perno
(CF)
Elisabetta Teti
(E)
C Vironet
(C)
Anders Lannergård
(A)
Ann-Sofi Duberg
(AS)
Soo Aleman
(S)
Tore Gutteberg
(T)
Alexandre Soulier
(A)
Aurélie Gourgeon
(A)
Stephane Chevaliez
(S)
Stanislas Pol
(S)
Fabrice Carrat
(F)
Dominique Salmon
(D)
Rolf Kaiser
(R)
Elena Knopes
(E)
Perpetua Gomes
(P)
Rob de Kneght
(R)
Bart Rijnders
(B)
Mario Poljak
(M)
Maja Lunar
(M)
Rafael Usubillaga
(R)
Carole Seguin Devaux
(C)
Enoch Tay
(E)
Caroline Wilson
(C)
Dao Sen Wang
(DS)
Jacob George
(J)
Jen Kok
(J)
Ana Belén Pérez
(AB)
Natalia Chueca
(N)
Miguel García-Deltoro
(M)
Ana María Martínez-Sapiña
(AM)
María Magdalena Lara-Pérez
(MM)
Silvia García-Bujalance
(S)
Teresa Aldámiz-Echevarría
(T)
Francisco Jesús Vera-Méndez
(FJ)
Juan Antonio Pineda
(JA)
Marta Casado
(M)
Juan Manuel Pascasio
(JM)
Javier Salmerón
(J)
Juan Carlos Alados-Arboledas
(JC)
Antonio Poyato
(A)
Francisco Téllez
(F)
Antonio Rivero-Juárez
(A)
Dolores Merino
(D)
María Jesús Vivancos-Gallego
(MJ)
José Miguel Rosales-Zábal
(JM)
María Dolores Ocete
(MD)
Miguel Ángel Simón
(MÁ)
Pilar Rincón
(P)
Sergi Reus
(S)
Alberto De la Iglesia
(A)
Isabel García-Arata
(I)
Miguel Jiménez
(M)
Fernando Jiménez
(F)
José Hernández-Quero
(J)
Carlos Galera
(C)
Mohamed Omar Balghata
(MO)
Joaquín Primo
(J)
Mar Masiá
(M)
Nuria Espinosa
(N)
Marcial Delgado
(M)
Miguel Ángel von-Wichmann
(MÁ)
Antonio Collado
(A)
Jesús Santos
(J)
Carlos Mínguez
(C)
Felícitas Díaz-Flores
(F)
Elisa Fernández
(E)
Enrique Bernal
(E)
José De Juan
(J)
José Joaquín Antón
(JJ)
Mónica Vélez
(M)
Antonio Aguilera
(A)
Daniel Navarro
(D)
Juan Ignacio Arenas
(JI)
Clotilde Fernández
(C)
María Dolores Espinosa
(MD)
María José Ríos
(MJ)
Roberto Alonso
(R)
Carmen Hidalgo
(C)
Rosario Hernández
(R)
María Jesús Téllez
(MJ)
Francisco Javier Rodríguez
(FJ)
Pedro Antequera
(P)
Cristina Delgado
(C)
Patricia Martín
(P)
Javier Crespo
(J)
Berta Becerril
(B)
Oscar Pérez
(O)
Antonio García-Herola
(A)
José Montero
(J)
Carolina Freyre
(C)
Concepción Grau
(C)
Joaquin Cabezas
(J)
Miguel Jimenez
(M)
Manuel Alberto Macias Rodriguez
(MAM)
Cristina Quilez
(C)
Maria Rodriguez Pardo
(MR)
Leopoldo Muñoz-Medina
(L)
Blanca Figueruela
(B)
Informations de copyright
© 2022 The Authors.
Déclaration de conflit d'intérêts
J.M.P. has been an advisor and/or speaker for AbbVie, Assembly Biosciences, Arbutus, Merck, Gilead, Regulus, and Memo Therapeutics. J.D. receives research support from Gilead. A.Y.M.H. is a consultant for Boston Pharmaceuticals. Outside the submitted work, J.G. reports grants and personal fees from AbbVie, Gilead Sciences, Merck, and Cepheid and grants from Hologic and Indivior. M.W.D has been an advisor and/or speaker for Gilead, AbbVie, and Merck and has received grants from Gilead and AbbVie. F.G.G. has been an advisor and/or speaker for AbbVie, Merck, and Gilead. S.F. has been an advisor and/or speaker for Abbott diagnostics, AbbVie, Gilead, and AB Science. F.C.S. has been an advisor and/or speaker for AbbVie, Merck, and Gilead and received grants from Merck and Gilead. Please refer to the accompanying ICMJE disclosure forms for further details.
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