This blog is the fifth in a series about the future of NIAID's HIV clinical research enterprise. For more information, please visit the HIV Clinical Research Enterprise page.

The outcomes of HIV clinical trials are often determined by precisely and accurately measuring how specific interventions work biologically in people. Whether tracking immune responses to a preventive vaccine candidate, monitoring changes to the amount of virus in the body, or screening for certain adverse events after administering a novel therapeutic, study teams routinely interact with clinical trial participants to safely obtain, store, transport, and analyze tissue and bodily fluid samples to answer important scientific questions about the impact of an HIV intervention in a laboratory. High quality, reliable laboratory infrastructure is critical to the accuracy and validity of clinical trial results. 

More than 150 NIAID-supported laboratories in 20 countries are addressing the diverse scientific programs of the four clinical trials networks in the Institute’s HIV clinical research enterprise. Since the start of HIV clinical research, laboratory capacities have grown in scope to support an increasing number of global clinical trials, emerging complexities in study protocol design and laboratory testing demands and evolving regulatory requirements for research and licensure.

NIAID is engaging research partners, community representatives, and other public health stakeholders in a multidisciplinary evaluation of its HIV clinical trials networks’ progress toward short- and long-term scientific goals. This process assesses knowledge gained since the networks were last awarded in 2020 to identify an essential path forward based on the latest laboratory and clinical evidence. Future NIAID HIV clinical research investments build on the conclusions of these discussions. 

In the next iteration of HIV clinical trials networks, laboratory functions will continue to evolve to align with scientific priorities and research approaches. Networks will support small early-phase trials, large registrational trials and implementation science research to examine preventive vaccine candidates and non-vaccine prevention interventions, antiviral treatments, HIV curative strategies, and therapies to improve the clinical outcomes of people affected by and living with HIV. Selected studies also will rely on high quality laboratory resources to examine interventions for tuberculosis, hepatitis, mpox and other infectious diseases. Clinical trial networks will need to employ a variety of laboratory types to achieve these objectives.  To increase flexibility and ensure the timeliness and the high quality standards the HIV field relies on for evidence that informs science, licensure and equitable practice, NIAID will have the ultimate authority for laboratory selection and approval.

Efficiency and Versatility 

Laboratory assays for HIV clinical trials continue to expand in quantity and complexity and require proportionate technical expertise and management. Future clinical research needs will include immunologic, microbiologic, and molecular testing, as well as standard chemistries and hematologic assays, with fluctuating volumes across a global collection of research sites. Balancing capacity, efficiency, scalability, and cost will require a mixed methods approach. These may include centralized laboratory testing where feasible and advantageous for protocol-specified tests; standardized processes for rapid assessment and approval of new network laboratories; and validated third-party outsourcing of routine assays to ensure timely turnaround when demands surge. 

Quality and Standardization

Ensuring consistent laboratory operations and high quality laboratory data will require continued compliance with the NIAID Division of AIDS Good Clinical Laboratory Practices and other applicable regulatory guidelines, ongoing external quality assurance monitoring, strong inventory management, importation and exportation expertise, and data and specimen management.

The research community plays an essential role in shaping NIAID’s scientific direction and research enterprise operations. We want to hear from you. Please share your questions and comments at NextNIAIDHIVNetworks@mail.nih.gov.

About NIAID’s HIV Clinical Trials Networks

The clinical trials networks are supported through grants from NIAID, with co-funding from and scientific partnerships with NIH’s National Institute of Mental Health, National Institute on Drug Abuse, National Institute on Aging, and other NIH institutes and centers. There are four networks—Advancing Clinical Therapeutics Globally for HIV/AIDS and Other Infections, the HIV Vaccine Trials Network, the HIV Prevention Trials Network, and the International Maternal Pediatric Adolescent AIDS Clinical Trials Network.

This blog is the fourth in a series about the future of NIAID's HIV clinical research enterprise. For more information, please visit the HIV Clinical Research Enterprise page.

The development of HIV therapy is one of the great success stories in modern infectious disease research, marked by rapid advances that scientists in the field could only dream of in the 1980s and 1990s. Once a handful of daily pills that only partially suppressed the virus and caused systemic adverse events, today’s antiretroviral therapy (ART) consists of highly effective, well-tolerated medications that can be taken in a single daily dose or a long-acting injection. ART not only offers individual benefits, but also suppresses viral replication to prevent onward transmission. The understanding that undetectable = untransmittable, also known as “U=U,” is based on the foundational NIAID-funded discovery that an undetectable HIV viral load makes it impossible to transmit the virus to sexual partners.

Today’s high standard of HIV care is possible because of the enduring effort of advocates and policymakers who insist that HIV science be sufficiently funded to address key evidence gaps and public health needs, as well as the research teams that propel a constant stream of discovery and the clinical trial participants who allow their lived experience to become evidence for a population-level benefit. This progress is extraordinary, but more advances are still needed to assure the long-term health and quality of life of all people with HIV. Among many persisting challenges, we must address HIV-related complications and conditions that share health determinants with HIV, including tuberculosis (TB), viral hepatitis and mpox.

NIAID supports four research networks as part of its HIV clinical research enterprise. Every seven years, the Institute engages research partners, community representatives, and other public health stakeholders in a multidisciplinary evaluation of network progress toward short- and long-term scientific goals. This process takes stock of knowledge gained since the networks were last awarded and identifies essential course corrections based on the latest laboratory and clinical evidence. Subsequent NIAID HIV research investments build on the conclusions of these discussions.

These investments are paying off. Recent scientific advances include:

• Basic and translational research that illuminated HIV’s structure, contributing to the development of the first drug in the capsid inhibitor class of antiretroviral drugs; 
• A U.S. clinical trial showing that long-acting injectable ART can support viral suppression in people who experience barriers to daily pill-taking;
• A global trial that found daily statin use reduces the risk of major adverse cardiovascular events in people with HIV;
• A large international clinical trial that found a one-month course of rifapentine and isoniazid was as safe and effective as a nine-month course of isoniazid for preventing active tuberculosis in people with HIV;
• Promising results from a hepatitis B virus (HBV) vaccine candidate for people with HIV who do not mount an immune response to current HBV vaccines;
• Evidence that sustained virological response to direct-acting antiviral therapy for hepatitis C virus (HCV) is possible with minimal clinical monitoring—a strategy that could be crucial to the global HCV elimination agenda; and
• Rapid engagement by the ACTG clinical trials network to examine antivirals for COVID-19 and mpox, demonstrating the essential role networks can—and should—play in pandemic preparedness and response.

We look forward to continuing to address the barriers that separate us from truly optimized HIV care. Our goals include fostering the next generation of discoveries that will open up possibilities for people with HIV—including people who have taken ART for decades—to experience a typical lifespan with high life quality, free from a chronic medication burden; reducing the incidence of concurrent TB and hepatitis; and ensuring scientific advances can feasibly be scaled to all who stand to benefit. 

Beyond Lifelong ART

Current therapeutic regimens are suppressive at best, meaning that if a person experiences an interruption in treatment, HIV replication will typically resume and continue to damage the immune system. Long-acting formulations are transforming quality of life for people who could not take daily ART, but their durability is measured in months, not years. While substantially extending the durability of ART is feasible, we will reach the limit of what long-acting molecules can do. Beyond the horizon of ART, we are exploring several strategies including gene therapy, administration of broadly neutralizing antibodies, and therapeutic vaccines that could either halt HIV replication for years or life or clear all HIV from the body—efforts collectively grouped under cure research. The design and development of cure strategies must advance technologies that could be implemented at scale, especially in resource-limited settings where HIV prevalence is high.

Non-HIV Pathogens 

Even when HIV replication is well-controlled with current therapy, the residual effects of infection can hamper a person’s immune responses and increase their likelihood of experiencing clinical disease from other pathogens. Several infectious diseases also share health determinants with HIV, and require researchers to consider the full constellation of biological, social, and structural factors that can threaten the health of people with HIV. Through collaboration with NIAID’s Division of Microbiology and Infectious Diseases and other NIH Institutes and Centers, we will ensure that we avoid resolving one health condition at the expense of another. We also need to ensure that interventions for non-HIV health conditions will work for people with HIV. Scientific priorities include developing shorter, safer, and more effective treatment regimens for all forms of TB, a preventive TB vaccine, and a hepatitis B cure. 

Quality of life

Conditions associated with aging can have greater impact on people with HIV, including (but not limited to) cardiovascular disease, diabetes, perimenopause, and dementia. HIV care models and tools are no longer sufficient if they only support viral suppression. Critical research is underway to define the ways that treated HIV exacerbates or accelerates other chronic conditions seen in older people. In partnership with other NIH Institutes and Centers, we will continue working to improve the quality of life for people with HIV by supporting research to prevent and treat HIV-related coinfections, complications and comorbidities through the lifespan. Furthermore, we will ensure that person-centered HIV care incorporates health-related quality of life metrics alongside standard HIV monitoring and management in our clinical trials. 

Equitable progress

Equity remains central to NIAID’s research and development decision-making. ART, once in short supply, is now globally available to most people living with HIV, and long-acting formulations herald a future of easier adherence schedules without the constant reminder of the burden of HIV. While our science has always focused on prioritizing concepts that could be rolled out to all populations who could benefit, we must provide an evidence base to support a faster translation of discovery to equitable health care service delivery. Implementation science and social science research including behavioral research, together with medical advances, can accelerate progress toward health equity. We seek to maintain a continuous feedback channel with implementers, so that our priorities are aligned with their most pressing challenges.

The research community plays an essential role in shaping NIAID’s scientific direction and research enterprise operations. We want to hear from you. Please share your questions and comments at NextNIAIDHIVNetworks@mail.nih.gov.

About NIAID’s HIV Clinical Trials Networks

Advancing Clinical Therapeutics Globally for HIV/AIDS and Other Infections is a global clinical trials network that conducts research to improve the management of HIV and its comorbidities; develop a cure for HIV; and innovate treatments for tuberculosis, hepatitis B, and emerging infectious diseases. The Network is supported through grants from NIAID, with co-funding and scientific partnership from the NIH National Institute of Mental Health, the NIH National Institute on Drug Abuse, the NIH National Institute on Aging, and other NIH Institutes and centers. Three other networks—the HIV Vaccine Trials Network, the HIV Prevention Trials Network, and the International Maternal Pediatric Adolescent AIDS Clinical Trials Network—generate complementary evidence on the scientific areas within their respective scopes.

A Year of Hepatitis Advances to Mark World Hepatitis Day

Viral hepatitis affects the lives of about one in twenty people in the world, resulting in over a million deaths each year. NIAID is working on many ways to prevent and treat the different types of hepatitis, including the development of vaccines and improved therapeutics and diagnostics. July 28 is observed annually as World Hepatitis Day, providing an opportunity to reflect on the impact of hepatitis on global health and focus on strategies to reduce its burden. To observe World Hepatitis Day, NIAID highlights recent advancements researchers have made in these areas.

Hepatitis is an inflammation of the liver, which can cause liver damage that is fatal in some cases. Most hepatitis cases are caused by viruses, although other infections, heavy alcohol use, exposure to toxins or some medications, or autoimmune disease can also cause hepatitis. There are five main virus types that cause hepatitis, types A, B, C, D and E. The different hepatitis viruses are spread in different ways, and each has unique impacts on health. Hepatitis A and E are generally spread through contaminated food and water, while hepatitis B, C and D are spread through body fluids. People with HIV have an increased risk of severe disease when hepatitis A, B, or C is present in the body. Additionally, presence of hepatitis B and C can affect treatment for HIV. Because of these interactions, people with HIV are disproportionately impacted by viral hepatitis.

Progress Towards Effective Hepatitis B Vaccines for People with HIV

Conventional vaccines against hepatitis B are sometimes unable to provide adequate immunity to people with HIV. An ongoing clinical trial is evaluating the effects of a vaccine against hepatitis B called HepB-CPG (also known as Heplisav-B) in people with HIV. HepB-CPG was shown to provide people with HIV high levels of immunity against hepatitis B. Researchers specifically looked at the effects of HepB-CPG vaccine in people with HIV who had previously not responded to conventional hepatitis B vaccines. The HepB-CPG vaccine uses an adjuvant—or immune booster—called CPG-1018. In the study, they compared HepB-CPG to a hepatitis vaccine that uses alum, a more conventional adjuvant, instead of CPG-1018. The researchers found that the vaccine containing CPG-1018 was superior to the conventional hepatitis B vaccine. The vaccines were safe and well tolerated. This work provides important evidence supporting the further development of vaccines for prevention of hepatitis B in people with HIV. The study is being led by ACTG, an NIAID-led clinical trials network. 

Exploring New Pathways of Immunity Against Hepatitis C

Hepatitis C can be cured with antivirals, but there are currently no vaccines against this type of hepatitis, due in part to the large number of variants and rapid evolution of the virus. People cured from hepatitis C can also become reinfected. The number of people diagnosed with hepatitis C is increasing, and a vaccine would be an important tool in preventing the spread of this dangerous virus, which can cause liver failure and cancer. Some people naturally clear hepatitis C from their bodies and have protective immunity against developing the disease when re-exposed to the virus. NIAID-funded researchers are investigating the immune responses in these individuals compared to those who develop persistent infections. The researchers found that neutralizing antibodies contributed to the clearance of hepatitis C virus from people’s bodies, and that these antibodies were directed to specific sites on the surface of the virus. Investigating how these antibodies are produced and how they target the virus may help researchers develop vaccines against hepatitis C. 

Advancing the Development of Vaccines Against Hepatitis E

Hepatitis E is the leading cause of acute hepatitis worldwide, causing about 20 million infections and 70,000 deaths each year, with greater impacts in regions with limited access to resources. There are no treatments for acute hepatitis E or approved vaccines against the virus. A vaccine is in development, called HEV-239, which was recently found in a NIAID-supported trial to be safe and achieve a durable immune response in adults in the United States. These promising results support the evaluation of the vaccine in in further clinical trials.

Understanding Hepatitis B-Associated Liver Cancer

NIAID researchers are studying diseases resulting from viral hepatitis-related liver damage, including a type of liver cancer called hepatitis B-associated hepatocellular carcinoma (HCC), which causes malignant tumors in the liver. Although immunotherapy can be effective to treat various forms of solid tumors, HCC-related tumors often do not respond to this treatment. To understand why, researchers carefully studied the tumor microenvironment—the specific molecular and cellular conditions that exist inside tumors—in 12 people with HCC. They found that two distinct subtypes of tumors existed in people with HCC. In about half of the people, the microenvironments of the tumors had high levels of immune activity, while lower levels were observed in the tumors in the other half of the people. This finding may help scientists understand how people with these types of HCC respond to treatments and could allow for development of treatments tailored to individuals with different subtypes.

New Animal Models for Hepatitis B and C

NIAID is funding several new projects focused on developing small animal models to understand and combat hepatitis B and C. This work is important because research on these viruses has been hindered by the lack of available animal models to study promising preventive and therapeutic concepts. Recipients of the new awards include:

• Wake Forest University for a project titled “Novel mouse models of hepatitis B virus infection and replication.” Guangxian Luo is the principal investigator. (Grant number: R01 AI183855-01.)
• The Research Institute at Nationwide Children’s Hospital for a project titled “Animal Model to study heterogeneous outcomes of HCV Infection and Pathogenesis. Amit Kapoor is the principal investigator. (Grant number: R01 AI183877-01.)
• The Rockefeller University for a project titled “Breaching the species barrier: Towards an immunocompetent HBV-susceptible mouse model.” Charles Rice is the principal investigator. (Grant number: R01 AI183884-01.)
• Georgetown University for a project called “Developing woodchucks susceptible to hepatitis B virus infection by modifying the virus or host.” Stephan Menne and Jianming Hu (at Penn State College of Medicine) are the principal investigators. (Grant number: R01 AI183788-01.) 

These advances and active projects underscore the important work NIAID is doing to prevent and treat viral hepatitis, with the aim of reducing the global burden of this disease. 

For more information, please visit NIAID’s hepatitis research page.

Sexually transmitted infections (STIs) are caused by bacteria, viruses, or parasites. STIs have a devastating impact on adults and infants and annually affect millions of people in the United States. Certain STIs can increase a person’s risk of developing cancer and increase the likelihood of acquiring or transmitting HIV. In addition, STIs can cause long-term health complications, especially in the reproductive and central nervous systems. In rare cases, they can lead to serious illness or death. 

NIAID supports research across the spectrum from basic to clinical science to develop effective diagnostic, preventive and therapeutic approaches to STIs in alignment with the National STI Strategic Plan. In recognition of National STI Awareness Week, NIAID shares a snapshot of new projects and recent scientific advances in STI research. 

Improving treatment for syphilis and trichomoniasis

New reports of syphilis and congenital syphilis are increasing at an alarming rate in the United States. Syphilis is caused by the bacterium Treponema pallidum. Benzathine penicillin G (BPG) is one of only a few antibiotics known to effectively treat syphilis. There is currently a shortage of BPG, and some people are allergic to penicillin antibiotics. In February 2024, NIAID convened a workshop with a wide range of experts on alternative therapies to BPG for the treatment of adult syphilis, neurosyphilis, and syphilis in pregnant persons and infants. The workshop addressed preclinical evaluation of candidate drugs, the potential need for studies on how candidate drugs are processed in the body during pregnancy, and how to approach clinical trials of treatment for congenital syphilis. This work is part of NIAID’s comprehensive portfolio of syphilis diagnosis, prevention, and treatment research. 

Trichomoniasis is the most common parasitic STI, caused by Trichomonas vaginalis. Trichomoniasis can increase the risk of getting or spreading other STIs, including HIV. The parasite can also cause inflammation of the cervix and the urethra. T. vaginalis is treated with an antibiotic drug class called nitroimidazoles. The currently recommended nitroimidazole, called metronidazole, cures 84-98% of T. vaginalis cases but does have high rates of breakthrough infection. A new project led by Tulane University will examine a single dose of secnidazole, a medicine in the same drug class, as a more effective and cost-effective treatment option for women and men. 

Developing a vaccine for herpes simplex virus 2

Herpes simplex virus 2 (HSV-2) is a common subtype of herpes simplex virus that is transmitted through sexual contact. The Centers for Disease Control and Prevention estimates that 18.6 million people aged 15 years and older United States live with HSV-2. In severe cases, HSV-2 may lead to life-threatening or long-term complications. There is no licensed preventive HSV-2 vaccine, and there is no cure. A new project led by the University of Pennsylvania seeks to define correlates of protection for HSV-2, meaning they intend to identify immune processes involved in preventing HSV-2 disease. They will do this by analyzing laboratory samples from animal studies of a promising preventive vaccine candidate that they developed with prior funding. That vaccine candidate is also now in an industry-sponsored early-stage clinical trial. The same project will expand on the HSV-2 targets in the preventive vaccine to develop a therapeutic vaccine concept to reduce recurrent outbreaks. This research responds to the scientific priorities in the NIH Strategic Plan for Herpes Simplex Virus Research.

Increasing fundamental knowledge of bacterial vaginosis 

Bacterial vaginosis (BV) results from an imbalance in the vaginal microbiome. BV can be caused by sexual activity, douches and menstrual products. BV can increase women’s biological susceptibility to HIV and other STIs and can cause premature birth or low birthweight if untreated in pregnant people. In a recent publication, NIAID-supported researchers, led by researchers at the University of Washington and University of California San Diego, shared findings on how damage to the vaginal skin barrier occurs during bacterial vaginosis. Those skin barrier cells, called epithelial cells, are covered in carbohydrate molecules called glycans. The research team found that people with BV had damaged glycans on their vaginal epithelial cells. They suggested that future work should examine the relationship between treatment and restoration of normal glycans. If an association is detected, it could help healthcare providers monitor for successful treatment outcomes to reduce the likelihood that BV will return after a course of treatment. The findings were published in Science Translational Medicine. 

These activities are among the research investments in NIAID’s STI portfolio. For more information on STIs, please visit:

• NIAID Diseases & Conditions: Sexually Transmitted Infections
• U.S. Department of Health and Human Services STI National Strategic Plan