TAGline/Volume 4 Issue 3
Nearly Everyone Agrees On the Need for 'Strategy' Type Clinical Studies -- And That's Where Consensus Ends
An intrepid Dr. Lange scales Mt. Sinai
First there was the CPCRA's "Moving Target" protocol, which entailed half a decade of arduous, dog-chasing-its-tail conference calls and draft after draft after endless draft of protocol revisions, each one more complicated than the next. Then, there was the Ellen Cooper behemoth at AmFAR's Community Based Clinical Trials Network (the CBCT), which boldly tempted fate with its characteristically arrogant acronym, "SMART." Most recently, the ACTG HIV RAC has thrown its hat into the antiretroviral strategy protocol ring with Michael Saag's "START" study.
Years later and countless two hour teleconferencing sessions since, "Moving Target" never budged; the sly "SMART" seems to have out-foxed even itself; and further development of "START" has been brought to a screeching halt. Why has it proven so difficult -- even among clinical trials groups with seasoned expertise and abundant financial resources -- to design a relatively long-term, but flexible, strategy-based antiretroviral study that many believe to be the only hope of obtaining answers to the thorny issues of long-term patient management? TAG's Spencer Cox, community representative to the ACTG's START protocol team, offers some insights.
This year's clinical research buzzword is undoubtedly "strategy." Almost everyone working in AIDS research agrees that strategy studies, which examine different ways of managing HIV-infected patients -- rather than the effects of particular drugs, are desperately needed. However, amidst raging controversy over what strategies should be tested, the ACTG's HIV Research Agenda Committee (RAC) has shot down proposals for ACTG 355 (the START protocol), the first major strategy trial to be proposed in the ACTG.
AdvertisementACTG 355, which was being developed by a team of researchers led by the University of Alabama's Dr. Michael Saag and Dr. William Powderly of Washington University, went through a number of incarnations with different primary questions. One draft would have tested "tight" control of viral load, in which patients attempted to maintain undetectable viral levels, versus "loose" control of viral load, in which patients with detectable virus levels below 5,000 copies/mL would have continued their current drug regimens. Another draft included a randomization between "immediate" and "deferred" protease inhibitors. In all drafts, patients and physicians would choose their therapies from a long list of available regimens.
In its review of the protocol, the HIV RAC noted that, "There is a critical need for a strategy protocol to prospectively validate observational studies on the clinical importance of viral RNA levels." However, the RAC also noted disagreements about what question the study would answer. Informal discussion between members of the research team and of the RAC suggested that some RAC members simply thought that investigators had chosen the wrong question: of course undetectable viral levels are preferable to maintenance of low but detectable viral levels, and early protease inhibitor use is better than late protease inhibitor use. Other RAC members quarreled with the specifics of the protocol's "decision tree" for which therapeutic regimens could be used. No one agreed on what the most important questions were: one investigator's speculative assumption is another investigator's career-making discovery.
Fundamentally, the problems faced by the ACTG 355 team are reflected in the current deliberations of two working groups, one established by the Public Health Service (PHS) and one assembled by the Office of AIDS Research (OAR) at the National Institutes of Health. These working groups are attempting to define guidelines for the treatment of HIV infection. While there is often surprising consensus on what specific recommendations to make, the PHS working group has spent hours discussing the caveats associated with their recommendations.
Aggressive treatment recommendations are sometimes being offered based on clinical interpretation of small, preliminary studies, rather than on larger, more reliable studies demonstrating improvement in clinical well-being. This raises questions about how to distinguish assumptions from demonstrated facts. For instance, no therapeutic regimen has been shown to be clinically superior to ddI monotherapy, however most knowledgeable investigators believe that the improved virologic response using AZT, 3TC and indinavir will necessarily improve outcome as compared to ddI.
Similarly, many investigators feel that the improved tolerance and virologic response using indinavir justifies its use as front-line therapy, however patient advocates and some clinicians worry that the tendency of indinavir to spawn multiple protease inhibitor cross-resistance may necessitate exploration of other alternatives.
What controversies need to be resolved by strategy studies? There is no consensus. In a presentation to the 4th Conference on Retroviruses and Opportunistic Infections, Dr. Joep Lange of the University of Amsterdam (who apparently was handed down the answers to these difficult questions on clay tablets) insisted that there are no major outstanding strategy questions: monitoring of viral load, tolerance and compliance will tell clinicians everything they need to know about the use of a particular regimen in a particular patient. According to Dr. Lange, the patient should start treatment "as soon as the patient is ready." Otherwise, he added, "HIV infection seems to me a pretty good reason to begin treatment."
This thorny situation came to a head in the PHS working group over the question of cross-resistance. All committee members agreed that clinicians need to know that current therapeutic choices will affect future options in the event of treatment failure. The committee also agreed that providing a wealth of information about genotypic resistance would not be terribly useful, as the data are confusing and their relationship to clinical response is not yet well characterized. However, without genotypic information, there is precious little evidence about how, in practice, sequencing of particular treatments may be important. Therefore the committee is asking clinicians to consider the future effects of current treatments without telling them specifically how to do so.
The ACTG 355 team hasn't called it quits yet. Investigators are currently working within the ACTG to develop a process for prioritizing strategy questions, with the hope of developing a new study proposal. There is also talk of preparing a scientific article for publication regarding the development of strategy trials.
Still, all of this may be interpreted as a not-so-great omen for the newly-founded Forum for Collaborative Research, a group of researchers, industry representatives, community advocates and insurers, that was formed to stimulate studies that would answer the most pressing clinical questions. If there is no consensus on what questions need to be answered, then it will be difficult to advocate for research. Additionally, at an upcoming closed-door meeting of the FDA's Antiviral Drugs Advisory Committee, pharmaceutical giant Glaxo-Wellcome is rumored to be developing a plan to minimize requirements for post-marketing research on their new drug, GW-1592U89. Without a strong FDA push for inclusion of strategy trials in post-marketing study plans, industry may not perceive a benefit to participation in these complex, long and expensive trials.
Ultimately, as usual, it is the patients who pay the price of this failure of will. It seems clear that clinical practice will be based on clinicians' best clinical judgment for some time to come. And, if history is any judge, that means AZT monotherapy for most patients living with HIV.
Opportunistic Infections Continue to Vex the Lives of PWAs as Long As Immunodeficiency Remains
'Postponing the inevitable'
Michael Marco and his TAG colleagues working within TAG's Opportunistic Infections Committee (Theo Smart, Laura Morrison, Tim Horn, Paul Dietz, Mark Harrington) released their 134-page OI Report at the national retroviral meeting in Washington, D.C. last month. The handsome volume includes summaries and analyses of the prevention and treatment of viral, bacterial, fungal and protozoal infections which threaten the lives and well-being of HIV-infected persons. A final section contains research policy recommendations. Washington University Medical School's Dr. Bill Powderly, who also heads the ACTG's OI committee, prepared this forward to the research report.
Opportunistic infections (OIs) remain the most important complications of HIV infection, resulting in profound morbidity and mortality. They clearly will remain a major issue as long as immunodeficiency is the inevitable result of long-standing HIV infection. As data from natural history studies show, while PCP prophylaxis has increased survival and delayed the onset of AIDS-defining illnesses, the inevitable is merely postponed. The advent of newer, more effective antiretroviral therapeutic regimens has clearly altered the equation in favor of the patient, but for many the question will be, "For how long?" Furthermore, it is clear that even for patients who experience effective antiviral responses to therapy, important questions regarding their immunocompetence and vulnerability to OIs remain.
The last ten years have elevated many once obscure pathogens to new prominence, and significant advances have been made. Just ten years ago, in 1987, opportunistic infection research was in its infancy. Pneumocystis carinii pneumonia (PCP) was by far the most common OI, with an associated mortality of 20-40%. Two drugs were available for therapy, trimethoprim-sulfamethoxazole (TMP/SMX), and pentamidine, and they were associated with dose-limiting toxicity in up to half of patients. Prophylaxis was used sparingly, only in certain parts of the country, and was not widely accepted. For the fungal infections, amphotericin B was the only available therapy, although phase I studies of the triazole antifungal agents fluconazole, itraconazole had been completed. For Toxoplasma encephalitis, pyrimethamine/sulfadiazine was effective, but it shared the same tolerability problems as TMP/SMX. Effective therapies for cytomegalovirus (CMV) retinitis, Mycobacterium avium complex (MAC) or acyclovir-resistant herpes simplex were not available or were not standardized and treatment was based on anecdotal information at best. The co-epidemic of tuberculosis was yet to be recognized.
We now have very effective therapies for many of the common opportunistic infections, such as PCP, tuberculosis, cryptococcosis and histoplasmosis; effective, but toxic therapies for toxoplasmosis and moderately effective treatment regimens for disseminated MAC and CMV infections. Only the enteric parasitic diseases such as cryptosporidiosis and micro-sporidiosis and the viral brain disease PML elude us in terms of at least modestly active treatment.
Yet these advances give us no reason for complacency. In some cases, we are just one short step, whether by drug toxicity or microbial mutation, away from a much less satisfactory situation. Clinicians well recognize the problems posed by sulfa-drug allergies in the management of PCP and toxoplasmosis, and by fluconazole-resistant fungal organisms such as Candida. Microbial resistance is increasingly an issue for mycobacterial and CMV infections as well. In too many cases, our successes are dependent on just one therapeutic agent, the loss of which may be catastrophic in terms of care.
The last ten years have also seen an increasing recognition that many OIs can be prevented. The use of prophylaxis for PCP has increased survival and delayed the onset of an AIDS-defining illness. The counterpart of this increased survival, however, is that patients using effective PCP prophylaxis have an increased risk of developing disseminated Mycobacterium avium complex (MAC), CMV disease, wasting syndrome and esophageal candidiasis -- as well as the opportunistic neoplasms such as Kaposi's sarcoma and lymphoma. Prevention of MAC has also proved to extend survival, and data also demonstrate that fungal and viral infections are preventable. However, this knowledge is tempered by the fact that multiple drug therapy for prevention of OIs is complicated by issues of toxicity, resistance, drug interactions, and cost. Thus, no consensus on how to best use multiple agents has yet been reached.
More effective antiretroviral therapy has provided new hope for many, and may be changing the course of OIs. Indeed, it could be argued that the most effective preventive therapy for all of the opportunistic infections will be more complete control of retroviral replication and with it better immunocompetence. It is clear that there are fewer OIs with the protease inhibitors -- both in clinical trials and in clinical practice. What is not clear is the extent or durability of the immunologic protection. Thus, the answer to a critical question for patients and doctors alike -- "Can I stop the prophylaxis?" -- is unknown. Clearly this question needs to be addressed by clinical researchers.
We all are glad to be in an era of optimism about the prospects for treating AIDS and HIV disease, and hope it will continue. Nonetheless, we must recognize that our current foundations are shallow, and must strive to improve our chances of overcoming these opportunistic pathogens. In many cases, while we have improved diagnosis, treatment and prophylaxis, our understanding of the microbial pathogenesis of these opportunistic organisms has not kept pace with our clinical advances. Yet only by developing a fuller understanding of the complex stages of the life cycles of these parasites, and their interactions with the human host immune defenses will we be able to keep up with their alarming ability to mutate away from antimicrobial control. Only increased research on the pathogenesis of the OI organisms will provide us with success. An important goal, therefore, is to define better predictors of certain OIs and thus identify subsets among patients with advanced HIV disease who are at increased risk for these infections. One approach is to attempt to use clinical parameters. Patients who have experienced one OI are at greater risk of developing a second, at any given CD4 count -- this is particularly true for MAC and CMV. Unfortunately, thus far these indicators merely identify relative rather than absolute risks and are not discriminatory enough to suggest strategies for prevention.
A more promising avenue is the use of microbiologic and immunologic markers, especially for CMV infection and MAC. As an example, the pathogenesis of CMV in patients with AIDS is far from clear. A majority of HIV-positive individuals have been exposed to CMV, yet only a minority develop overt CMV disease. A high proportion of individuals with advanced HIV disease are CMV viremic and/or viruric, yet many of these never have overt CMV disease. Several reports have suggested that CMV virologic measures might be predictive of invasive CMV disease, especially retinitis. If confirmed then it might be possible to identify patients at high risk of developing CMV disease. In that case, regular screening for early evidence of viral replication by polymerase chain reaction (PCR) might be useful in targeting early intervention, rather than true prophylaxis. Additionally, certain OI-specific immune response (or perhaps loss of specific OI responses) may be critical in the development of certain infections. These too could be used to better target prevention or early treatment. What is clear is that this should be a high priority for clinical and basic research in this arena.
Treating OIs: How We're Doing
- "Very effective" therapies for:
- Pneumocystis pneumonia (PCP)
- tuberculosis (TB)
- "Effective, but toxic" therapies for:
- toxoplasmic encephalitis
- "Moderately effective" therapies for:
- Mycobacterium avium complex (MAC)
- cytomegalovirus (CMV)
- "No active treatments" for:
- progressive multifocal leukoencephalopathy