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Treatment Failure, Resistance, and 2 nd line ART in Resource-Limited Settings Chris Behrens, MD May 2009. Detecting and Managing Treatment Failure in the absence of virologic monitoring.
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Treatment Failure, Resistance, and 2nd line ART in Resource-Limited Settings Chris Behrens, MD May 2009
Detecting and Managing Treatment Failure in the absence of virologic monitoring • While access to CD4 testing has expanded considerably in recent years, access to routine viral load testing remains scarce in resource-limited settings • Clinicians are therefore obliged to monitor patients on HAART using only clinical & immunologic criteria to detect treatment failure • How well does this approach work?
Time-Sensitivity of different failure definitions for detecting Tx Failure Viral Load Clinical Status CD4 Count Time Tx Failure Immunologic detection Clinical detection Virologic detection
Case 1 • 33 yo male on HAART after being diagnosed with pulmonary TB, CD4 = 220 • Now has completed TB therapy, doing well on HAART with rise in CD4 count • You do not have access to viral load monitoring, hence for this (and all your other patients) you rely on WHO clinical and immunological (CD4) criteria to detect treatment failure • How sensitive is this screening method for detecting treatment failure? How likely is it that your patients are failing therapy, but failure is not being detected?
Case 2 • 27 yo female on HAART for past year, seen for routine follow-up • Initial CD4 count 180, WHO Stage III • Reports excellent adherence. Feeling well. PE unremarkable • CD4 counts: • How should you manage this patient? How likely is it that this patient is truly failing treatment?
Case 3 • 41 yo female on AZT/3TC/NVP for two years, seen for routine follow-up • Initial CD4 count 210, WHO Stage III • Reports excellent adherence. Feeling well. PE unremarkable, but CD4 counts are falling • Your national guidelines recommend a switch to 2nd line ART • What 2nd line regimen would be most appropriate? • How likely is it that she will respond to the 2nd line HAART regimen? What is the most effective 2nd line ART regimen patients like her? How well do 2nd line regimens work in this scenario?
How useful is it to detect treatment failure based on immunologic & clinical criteria? • How accurately does this strategy detect patients who are truly failing therapy? • What are the resistance profiles in patients whose failure is detected by immunologic/clinical criteria? • What options do these patients have for 2nd line ART? • How effective is empirically-designed 2nd line ART for these patients?
Some Key Definitions • 1st line regimen: “the initial regimen prescribed for a naïve patient when the patient fulfills national clinical and laboratory criteria to start ART.” • 2nd line regimen: “the next regimen used in sequence immediately after first-line therapy has failed” • Treatment failure: “the loss of antiretroviral efficacy [that] triggers the switch of the entire regimen from first to second line” • Note: single substitutions of ARVs (usually within the same class) for toxicity, drug-drug interactions, or intolerance to not indicate a 2nd line regimen is being used. WHO: Prioritizing Second Line ART within a Public Health Approach, 2007
Key Definitions, continued • Treatment Failure: • “loss of antiretroviral (ARV) efficacy, prompting a switch of the entire regimen from first- to second-line.” - WHO, 2007 • “absence of a sustained favourable response to antiretroviral therapy” - 2007 Caribbean Guidelines • How do we recognize Treatment Failure? • Clinical Failure • Immunologic Failure • Virologic Failure
Detecting Treatment Failure Antiretroviral Therapy for HIV Infection in Adults and Adolescents in Resource-Limited Settings (WHO, 2006)
How useful is it to detect treatment failure based on immunologic & clinical criteria? • How accurately does this strategy detect patients who are truly failing therapy? • What are the resistance profiles in patients whose failure is detected by immunologic/clinical criteria? • What options do these patients have for 2nd line ART? • How effective is empirically-designed 2nd line ART for these patients?
Case 1 • 33 yo male on HAART after being diagnosed with pulmonary TB, CD4 = 220 • Now has completed TB therapy, doing well on HAART with rise in CD4 count • You do not have access to viral load monitoring, hence for this (and all your other patients) you rely on WHO clinical and immunological (CD4) criteria to detect treatment failure • How sensitive is this screening method for detecting treatment failure? How likely is it that your patients are failing therapy, but failure is not being picked up by checking CD4 counts?
Performance of WHO Clinical & Immunologic Criteria in detecting Virologic Treatment failure 1. Int J Infect Dis 2007; 11:413–416. 2. AIDS 2008; 22:1971–1977. 3. AIDS 2009, 23:697–700
Case 2 • 27 yo female on HAART for past year, seen for routine follow-up • Initial CD4 count 180, WHO Stage III • Reports excellent adherence. Feeling well. PE unremarkable • CD4 counts:
27 yo woman on HAART for one year, CD4 back to baseline of 180, clinically stable • How would you classify and manage this patient? • This likely represents treatment failure: switch to 2nd line ART • This might be treatment failure; repeat CD4 count and switch to 2nd line regimen if CD4 remains 180 or below; • Continue therapy without change since this does not likely represent treatment failure How likely is it that this patient is truly failing treatment?
Performance of WHO Clinical & Immunologic Criteria in detecting Virologic Treatment failure 1. Int J Infect Dis 2007; 11:413–416. 2. AIDS 2008; 22:1971–1977. 3. AIDS 2009, 23:697–700
How useful is it to detect treatment failure based on immunologic criteria? • How accurately do immunologic criteria detect patients who are truly failing 1st-line therapy? • What are the resistance profiles in patients whose treatment failure is detected by immunologic criteria? • What options do these patients have for 2nd line ART? • How effective is empirically-designed 2nd line ART for these patients?
Resistance profile of patients failing First Line ART in Malawi when using Clinical and Immunologic Monitoring • Clinical ART failure • New WHO Stage IV condition • Progressive WHO Stage IV condition • Immunological ART failure • > 50% Decline from peak or below pre-treatment value • ART failure confirmed with HIV-RNA > 400 copies/ml • Resistance test if viral load >1000 copies ml • Genotypic analysis (TruGene) • Phenotype (Monogram) for complex genotypes 17th IAC, Mexico City 2008, Abstract TUAB0105
Malawi: resistance patterns in patients failing first line ART • On d4T/3TC/NVP or alternative first line (ZDV for d4T toxicity, EFV for NVP toxicity) • Enrollment from Dec 2005 to Jun 2007 • 96 patients identified as ART Failure with VL>1000 copies • 16 clinical (WHO Stage IV), 87 Immunological (CD4 decline) • 66 on d4T/3TC/NVP, 30 on ZDV/3TC/NVP • 2 samples did not amplify => 94 samples for analysis 17th IAC, Mexico City 2008, Abstract TUAB0105
Common Mutations • M184V or M184I 81% • NNRTI mutations 93% • Median 2 (range 0-3) • 181C 55%, 190A 30%, 103N 28% • Wild Type Virus 5% • M184 only 0% • NNRTI mutations only 2% • M184V & NNRTI mutations only 16% 17th IAC, Mexico City 2008, Abstract TUAB0105
Thymidine Analogue Mutations (TAMs) • 56% of patient samples had TAMs • 28% with one • 28% with 2 • 44% with 3 or more 17th IAC, Mexico City 2008, Abstract TUAB0105
Multivariate analysisemergence K65R or K70E resistance OR 95% CI CD4 count <100 cells/ml 6.1 1.47 – 25.0 Use of AZT 0.18 0.04-0.94 17th IAC, Mexico City 2008, Abstract TUAB0105
Multivariate analysisemergence PAN-NRTI resistance OR 95% CI CD4 count <100 cells/ml 9.8 1.16 – 82.9 Use of AZT 0.12 0.014 – 0.978 17th IAC, Mexico City 2008, Abstract TUAB0105
TAM Pathways • Pathway I: 41L, 210W, 215Y • Associated with d4T use • Confers high-level AZT resistance and cross-resistance to other NRTIs, esp ddI and tenofovir • Pathway II: 70R, 67N, 215F, 219Q/E • Associated with AZT use • leads to less NRTI cross-resistance
Implications • High level resistance to 3TC/FTC and to NNRTIs very common in patients who fail 1st line therapy • 2nd line regimen will need to be ‘anchored’ by a ritonavir-boosted PI • Challenge is to design a useful 2nd line NRTI backbone to complement the r/PI • Use of AZT rather than d4T in first line ART regimen better preserves 2nd line NRTI options • AZT prevents emergence of mutations associated with TDF resistance (K65R, K70E), which d4T can select for especially in HIV subtype C strains • Resistance to AZT associated with TAM II pathway, which confers less pan-NRTI resistance
How useful is it to detect treatment failure based on immunologic & clinical criteria? • How accurately does this strategy detect patients who are truly failing therapy? • What are the resistance profiles in these patients? • What options do these patients have for 2nd line ART? • How effective is empirically-designed 2nd line ART for these patients?
a 3TC and FTC are considered interchangeable because they are structurally related and share pharmacological properties and resistance profile. b NFV does not need refrigeration and can be used as a PI alternative in places without cold chain. c 3TC can be considered to be maintained in secondline regimensto potentially reduce the viral fitness, confer residual activity and maintain pressure on the M184V mutation to improve viral sensitivity to AZT or TDF. AZT may prevent or delay the emergence of K65R mutation. d There are insufficient data to detect differences among available RTV-boosted PIs (ATV/ r, FPV/r, IDV/r , LPV/r and SQV/r ) and the choice should be based on individual program priorities (see text). In the absence of a cold chain, NFV can be employed as the PI component but it is considered less potent than a RTV-boosted PI. Antiretroviral Therapy for HIV Infection in Adults and Adolescents in Resource-Limited Settings (WHO, 2006)
ART backbone- 2 fully active NRTIs 17th IAC, Mexico City 2008, Abstract TUAB0105
ART backbone- No fully active NRTIs 17th IAC, Mexico City 2008, Abstract TUAB0105
2nd line ART options for Malawi patients failing 1st line HAART • Based on resistance analysis, most potent 2nd line regimen among WHO options is TDF + AZT + 3TC/FTC + r/PI • Highest percentage of patients with 2 fully active NRTIs • Lowest percentage of patients with no fully active NRTIs 17th IAC, Mexico City 2008, Abstract TUAB0105
Synergy of TDF and AZT in 2nd line regimens for patients failing typical 1st line regimen • Unless HIV has evolved multiple TAMs before switch to 2nd line regimen, the virus will likely be at least partially sensitive to both AZT and TDF • Combining AZT and TDF in the 2nd line regimen makes it very difficult for HIV to evolve resistance to both agents simultaneously • K65R mutation reverses TAM-mediated AZT resistance* • Only option for HIV would be to evolve more TAMs, which is difficult with TDF and an active PI in the regimen • This strategy may not work, however, for patients in whom failure is detected relatively late, as multiple TAMs impart high-level resistance to AZT and TDF (as well as d4T, ddI, and ABC) * Antivir Ther. 2006;11(2):155-63
Retain 3TC/FTC in 2nd line regimens? • The M184V mutation ‘hobbles’ HIV in two important ways: • Reduced replication capacity (approximately 1/2 log) - virus is less ‘fit’ • Partially reverses TAM-induced resistance to AZT, d4T, and TDF • Keeping 3TC (or FTC) in the 2nd line regimen forces HIV to maintain this inconvenient M184V mutation • 3TC (as well as FTC) is relatively well-tolerated, can be dosed once-daily, is present in many FDCs • Clinical outcomes data from a RCT suggests benefit of keeping 3TC in ‘salvage’ regimens* *Castagna A et al. E-184V study. Third IAS Conference, abstract WeFo0204, 2005.
How useful is it to detect treatment failure based on immunologic & clinical criteria? • How accurately does this strategy detect patients who are truly failing therapy? • What are the resistance profiles in these patients? • What options do these patients have for 2nd line ART? • How effective are empirically-designed 2nd line ART regimens for these patients?
2nd line ART Responses: Malawi • 101 patients switched to 2nd line ART on the basis of WHO clinical/immunological criteria for failure • 2nd line ART regimen: AZT/3TC/TDF/r-LPV • 12 months of follow-up: • 10 patients died; • 3 lost to follow-up; • 85% of remaining had VL < 400 at 12 months • Resistance patterns in these patients did not predict response! 16th CROI, Montreal, 2009, abstract 605
2nd line ART Responses: South Africa • N = 382 patients from Themba Luthu clinic (Johannesburg) switched to 2nd line ART regimen of AZT/ddI/r-LPV • 89% of patients alive and in care one year after switch • 78% had undetectable viral load • No data on response according to resistance profile 16th CROI, Montreal, 2009, Abstract 606
2nd line ART Responses: Cambodia • N = 113 patients switched to 2nd line HAART regimen of ddI/3TC/r-LPV • 89% of patients had undetectable viral load a median of 10 months later • No data on response according to resistance profile 14th CROI, Los Angeles, 2007, abstract 36LB
Favorable responses to 2nd line ART – but will it last? • Success of 2nd line ART in these settings may mostly reflect potency of r-LPV • Several studies suggest high efficacy of r-LPV monotherapy in patients who are naïve to ART or well-controlled on HAART • MONARK*: r-LPV monotherapy not as potent as traditional HAART in non-clade B HIV subtypes *11th European AIDS Conference, Madrid 2007, abstract PS1/2
Broader access to viral load testing for routine monitoring? • Pros: Would allow for earlier detection of treatment failure & earlier switch to 2nd line • Avoid immunologic/clinical decline; • Minimize evolution of NRTI resistance • Eliminate unnecessary/premature regimen switches • Rakai, Uganda*: almost as many people were being switched unnecessarily as were being missed treatment failure; would have cost an estimated extra $75,000/year in 2nd line drugs • Cons: cost, laboratory infrastructure, turn-around time: point-of-care technology needed! *16th CROI, Montreal 2009, abstract 144
Remaining Questions • Should 1st line HAART regimens in RLS use TDF instead of AZT or d4T? • Advantages: • well-tolerated, convenient dosing • Activity of AZT likely in patients who fail TDF* • Disadvantages: • Cost • K65R with failure of TDF-based regimen => compromised efficacy of ABC, ddI for future use *Landman R et al. Successful rescue therapy in patients developing K65R on tenofovir-containing regimens: long-term follow-up. Twelfth Conference on Retroviruses and Opportunistic Infections, Boston, abstract 710, 2005b
Remaining Questions • Should 1st line HAART regimens include both TDF and AZT? • Advantages: • Improved durability: HIV has difficulty evolving resistance simultaneously to both drugs • Disadvantages: • Cost • Toxicity • Failure (though rare) could leave very few 2nd line options
Remaining Questions • When will newer agents become available in resource-limited settings? • Etravirine: new NNRTI active against most strains of HIV that have evolved resistance to EFV, NVP • Darunavir: new PI active against most strains otherwise resistant to PIs • Raltegravir: integrase inhibitor • Maraviroc: CCR5 Inhibitor
Second line ARV drugs in adults and adolescents Standard second-line option if NRTI/NNRTI approach were used in first-line therapy ddI or TDF PI/r* EFV or NVP NRTI sparing option if the triple NRTI approach were used in first-line therapy ABC or 3TC (±AZT)# * Ritonavir-boosted PIs (ATV/r, FPV/r, IDV/r, LPV/r and SQV/r) are considered as the key component in second-line regimens and its use should be reserved for this situation. LPV/r is the only PI currently available as a FDC and a new formulation that doesn't need refrigeration was recently launched. In the absence of a cold chain and where the new LPV/r formulation is not available, NFV can be employed as the PI component but it is considered less potent than a RTV-boosted PI. # The use of 3TC (±AZT) are listed for “strategic” use as resistance to both drugs is predicted to be present following failure on the respective first-line regimen listed. 3TC will maintain the M184V mutation which may potentially decrease viral replicative capacity as well as induce some degree of viral resensitization to AZT or TDF; AZT may prevent or delay the emergence of the K65R mutation. However, it must be stressed that the clinical efficacy of this strategy in this situation has not been proven.
Antiretroviral Therapy for HIV Infection in Adults and Adolescents in Resource-Limited Settings (WHO, 2006)
Detecting Treatment Failure Antiretroviral Therapy for HIV Infection in Adults and Adolescents in Resource-Limited Settings (WHO, 2006)
When to Switch from 1st Line to 2nd Line ARV Regimens for Treatment Failure Clinical failure is defined as a occurrence of new or recurrent WHO clinical stage 3 or 4 event (excluding IRIS). CD4 failure is defined as a fall to (or below) the pre-treatment baseline or a 50% drop from the on-treatment peak level or persistent levels < 100 cells/mm3. Virological failure is provisionally defined as a plasma HIV-1 RNA level >10,000 copies/ml after a minimum of 6 months on therapy. Antiretroviral Therapy for HIV Infection in Adults and Adolescents in Resource-Limited Settings (WHO, 2006)
2006 WHO guidelines • Immunologic Failure if: • the CD4 cell count falls below baseline in the absence of other concurrent infections, • the CD4 cell count falls to less than 50% of peak levels without coexistent infections, or • the CD4 cell count is consistently below 100 cells/ml. • For either of the first two criteria, switching therapy NOT recommended for asymptomatic patients if the CD4 cell count remains above 200 cells/ml.
Performance of WHO Immunologic Failure Criteria – Rakai, Uganda • N =1133 participants enrolled in antiretroviral treatment program between June 2004 and September 2007, median follow-up 20.2 months • WHO immunologic failure criteria were reached by 125 (11.0%) participants. • virologic failure* reached by 112 participants (9.9%). • Only 26 participants (2.3%) experienced both an immunologic and virologic failure endpoint (2 viral load>400 copies/ml) during follow-up. AIDS 2009, 23:697–700 *defined as HIV-1 viral load more than 400 copies/ml on two measurements