Active clinical trials for "Triple Negative Breast Neoplasms"

This is a multicenter, open-label, phase Ib/IIa study. The first part of the study will evaluate the safety, tolerability and preliminary efficacy of ILB2109 and Toripalimab in patients with locally advanced or metastatic solid malignancies. The second part of the study will evaluate the efficacy of ILB2109 and Toripalimab in patients with selected advanced solid malignancies.

This is a feasibility study to gain preliminary information regarding whether breast imaging with or without a core needle biopsy after neoadjuvant chemotherapy (NAC) but before surgery can accurately predict complete pathologic response (pCR) in women with triple negative or HER2- positive breast cancer. pCR is defined as having no residual invasive breast cancer or ductal carcinoma in situ.

ARGONAUT is a longitudinal, prospective, observational study that will enroll up to 5,000 advanced-stage cancer patients of diverse racial backgrounds to collect data used to develop precision microbiome medicines and for the identification of clinically actionable cancer-specific biomarkers to guide therapeutic decisions. Four types of solid tumor cancers will be profiled including non-small cell lung cancer (NSCLC), triple negative breast cancer (TNBC), colorectal cancer (CRC) and pancreatic cancer. Healthy control subjects without a cancer diagnosis will also be studied, comprised of individuals at high risk for CRC and healthy individuals at low risk for CRC. Risk assessment will be based on family history or past neoplastic findings during CRC screening. Data collected from this study will be used to develop the most effective new therapies, via microbiome optimization, all to the benefit of patients and the physicians treating them. Stool and blood samples will be collected longitudinally and analyzed to determine the impact of gut microbiome composition and function on the immune system and efficacy of the treatment. Currently enrolling the CRC, high risk, and low risk cohorts. Subjects who meet the entry criteria will provide up to 5 samples each of blood and stool over a 2-year period. Approximately 10%-20% of the subjects will provide colon tissue samples, either from research biopsies during Standard of Care (SOC) screening colonoscopy or retained surgical tissue from colectomy. Electronic health records will be obtained at various times for up to 8 years, to collect tumor imaging results and any other updated medical data, with no additional samples collected. In select cases, stool and blood samples will be collected beyond 2 years.

This clinical trial is a multicenter, randomized, open-label, phase-II study to evaluate the efficacy and safety of maintenance treatment with eribulin mesylate following standard adjuvant chemotherapy in triple negative breast cancer patients.

The microbiome has the potential to serve as a robust biomarker of clinical response to immunotherapy. Additionally, microbial manipulation, through diet, exercise, prebiotics, probiotics, or microbially-derived metabolites, may prove to be beneficial in promoting anti-tumor immune responses. However, large prospective studies in humans with longitudinal sample collection and standardized methods are needed to understand how microbiota and their byproducts affect cancer therapies, particularly among patients undergoing identical therapy but experiencing different outcomes. The proposed observational study builds upon these hypotheses by proposing a large cohort design to further assess the associations between the gut microbiota (composition and function), host immune system, and ICI treatment efficacy across multiple cancer types.

The study is a single arm, nonrandomized phase II prospective study, with the goal of investigating the role of screening brain MRIs in neurologically asymptomatic patients with metastatic breast cancer.

Cancer is a condition where cells in a specific part of body grow and reproduce uncontrollably. The purpose of this study is to assess adverse events and change in disease activity when ABBV-400 is given to adult participants to treat advanced solid tumors. ABBV-400 is an investigational drug being developed for the treatment of advanced solid tumors. Study doctors put the participants in groups called cohorts. Each cohort receives ABBV-400 alone (monotherapy) followed by a safety follow-up period. Approximately 220 adult participants with hepatocellular carcinoma (HCC), pancreatic ductal adenocarcinoma (PDAC), biliary tract cancers (BTC), esophageal squamous cell carcinoma (ESCC), triple negative breast cancer (TNBC), hormone receptor+/human epidermal growth factor receptor 2 negative (HER2-) breast cancer (hormone receptor-positive [HR+]/HER2-breast cancer [BC]), head and neck squamous-cell-carcinoma (HNSCC), or advanced solid tumors, will be enrolled in the study in approximately 60 sites worldwide. In the each cohorts, participants with the following advanced solid tumor indications: HCC, PDAC, BTC, ESCC, TNBC, HR+/HER2-BC, and HNSCC will receive intravenous (IV) ABBV-400 monotherapy for up to 2 years during and up to the treatment period with an additional safety follow-up period of up to 2 years. There may be higher treatment burden for participants in this trial compared to their standard of care. Participants will attend regular visits during the study at an approved institution (hospital or clinic). The effect of the treatment will be frequently checked by medical assessments, blood tests, questionnaires and side effects.

Summary Points: High Risk Breast Cancers: Triple negative cancer is considered high risk due to high rate of local and systemic failure. Newer innovative treatment strategies are needed to improve systemic control of disease and survival. Immune system modulation: is an emerging modality in cancer treatment. Tumor antigens can stimulate T cells to identify and destroy cancer cells. Cancers express "altered self" antigens that tend to induce weaker responses than the "foreign" antigens expressed by infectious agents. Thus, immune stimulants and adjuvant approaches have been explored widely. Opportunities to develop effective cancer vaccines may benefit from seminal recent advances in understanding how immunosuppressive barricades are erected by tumors to mediate immune escape. This concept is precisely applicable to triple negative breast cancer due to their antigenicity. Checkpoint inhibitors are an attractive method for treatment of high-risk breast cancers. However, to leverage the efficacy of checkpoint inhibition, approaches are needed to enhance delivery of cancer antigens to the T cells. Cryoablation: offers an efficacious and safe method to enhance tumor antigen presentation to the immune cells while destroying the primary tumor. This ablation method is superior by virtue of antigen preservation in situ despite toxicity to the tumor cell. Impact of cryoablation in enhancing immunological responses in tumor microenvironment are well established; however, cryoablation can also cause tumor antigen tolerance via non-specific stimulation of T cells. Rationale for combining cryoablation and checkpoint inhibitors: Since checkpoint inhibitors curtail the tolerance developed by tumor antigens, and cryoablation enhances antigen presentation and T cell recruitment, it is intuitive that combination of these two approaches presents an ideal opportunity to leverage the benefits of both approaches while curtailing the limitations of either. Therefore, the investigators hypothesize in this study that their combination will improve the response rate and the degree of response.

This is a Phase II, open-label, Single-center platform study research based on molecular subtypes to explore precision therapy in refractory triple-negative breast cancer.

The diverse group of breast tumors known as triple-negative breast cancer (TNBC) which is lethally and deadly type of breast cancer and insensitive to endocrine therapy and HER2-targeted therapy because it lacks the expression of estrogen, progesterone, and human epidermal growth factor receptors TNBC makes up almost 15% of all invasive breast cancers, and of all breast tumor subtypes, it has the worst overall survival and the highest rate of metastatic occurrence. Cytotoxic chemotherapy is the main established systemic therapy for early and advanced TNBC disease at the moment because there is no authorized targeted therapy. Despite the fact that chemotherapy greatly improves clinical outcomes for TNBC patients, recurrence rates are still high and TNBC cancers frequently develop chemotherapeutic drug resistance ). In light of the few available therapy choices, so few choices for this subtype of breast cancer, and many cases are resistant to chemotherapy and recurrent and with a risk of high metastasis from previous literature and many experimental studies, the target of glucose environment is a promising weapon against this deadly type of breast cancer so glucose deprivation from tumor cells may cut the glucose entry as fuel to these cancer cells so this study uses a substitute energy fuel by using alkaline glucosodiene which is chemically invented by Maher M.AKL