View clinical trials related to Ovarian Neoplasms.
Filter by:This is a first-in-human, Phase 1, open label, multicenter, multiple dose, dose escalation and dose expansion study intended to evaluate the safety, pharmacokinetic, pharmacodynamic and potential clinical benefit of PF-07257876, a CD47-PD-L1 bispecific antibody, in participants with selected advanced or metastatic tumors for whom no standard therapy is available. The study contains 2 parts, single agent Dose Escalation (Part 1) to determine the recommended dose of PF-07257876, followed by Dose Expansion (Part 2) in selected tumor types at the recommended dose.
In Phase I the sponsor will systematically test conditions for lavage filtration that increase tumor cell fraction without reducing tumor mutation yield. The Sponsor will also transition all lavages to luteal phase timing, when endometrial shedding is least. In Phase II the Sponsor will examine our data in context of clinical characteristics, particularly age, to develop a multivariate model that determines optimal mutant allele frequency (MAF) diagnostic threshold by patient. Furthermore, the sponsor will explore a highly innovative idea, entailing empirically determining each individual's background mutation load, agnostic of the aging or mutagenic exposures responsible, and using this as a personalized calibrator to determine optimal MAF diagnostic threshold.
This project is about exploring a novel method to detect ovarian and uterine cancers earlier and better. More precisely, a high-performance radioactive estrogen analog will be used to visualize hormone-sensitive uterine and ovarian tumors using PET imaging. Not only this imaging methodology could improve the whole-body assessment of those diseases, but will also hint clinicians about the optimal course of therapy to undertake. The lead investigator's team designed in the past years an innovative radioactive estrogen derivative tracer (4FMFES) for the medical imaging modality termed Positron Emission Tomography (PET). The compound was first shown to be safe for human use. Recently, a clinical trial demonstrated that 4FMFES-PET is superior to any existing comparable tracer for detection of hormone-sensitive breast cancer patients. 4FMFES is particularly useful to pinpoint unsuspected metastases early, which allowed better breast cancer patient management and staging. 4FMFES and standard FDG PET imaging were shown to be complementary in breast cancer, the use of both techniques together providing a detection rate nearing 100%. Since ovarian and uterine cancers are about as likely to be targeted by 4FMFES as breast cancer, the use of this novel precision imaging method will be adapted to those other indications. In general, the sooner a cancer is diagnosed and treated, the better the outcome of a patient will be. Gynecological cancers lack precise screening and detection tools. In particular, while a majority of uterine cancers are relatively well managed, patients burdened with metastatic burden have a much worse prognosis, and precise and early detection of those lesions will greatly help clinicians to better treat those complicated cases. As for ovarian cancers, they are usually devoid of clinical symptoms until late onset, which partly explain the high mortality rate of this disease. Hence, for both diseases, a precision, whole-body imaging technique will allow earlier assessment, followed by earlier intervention, resulting in improved survival rate and better quality of life for patients.
The study evaluates the level and molecular profiles of different CTC populations as markers for predicting the risk of developing hematogenous metastases and the effectiveness of treatment in patients with tumors of the female reproductive system (breast cancer, endometrial cancer, and ovarian cancer). The primary objective are: 1. To assess the presence and number of different populations of CTCs at different time points (before biopsy, before surgery, and after surgery). 2. To assess the relationships of different CTCs populations prior to treatment initiation with the effects of neoadjuvant chemotherapy and the risks of recurrence and metastases. 3. To assess the molecular profiles of different CTCs populations in the blood and in ascitic fluid. The secondary objective is to compare the multicolor flow cytometry results with data of ultrasound, CT and/or MRI, serum tumor markers, and immunohistochemical studies in patients with breast cancer, endometrial cancer and ovarian cancer
Retrospective observational study of patients treated with niraparib in an individual patient access program in Norway.
This phase II trial investigates the effect of irinotecan liposome and bevacizumab in treating patients with ovarian, fallopian tube, or primary peritoneal cancer that shows less response to platinum therapy (platinum resistant), has come back (recurrent), or does not respond to treatment (refractory). Irinotecan liposome may help block the formation of growths that may become cancer. Bevacizumab is a monoclonal antibody that may interfere with the ability of tumor cells to grow and spread. Giving irinotecan liposome and bevacizumab may kill more cancer cells.
Primary objective: To evaluate the pharmacokinetic effects of fluzoparib on caffeine, S-warfarin, omeprazole, midazolam, repaglinide and bupropion in patients with recurrent ovarian cancer. Secondary objective: To evaluate the safety of single dose of fluzoparib, caffeine, S-warfarin, omeprazole, midazolam, repaglinide and bupropion or fluzoparib in combination with caffeine, S-warfarin, omeprazole, midazolam, repaglinide and bupropion in patients with recurrent ovarian cancer.
Molecular alterations in Homologous Recombination Repair (HRR) genes have been associated with clinical benefit from chemotherapy and/or Poly (ADP-ribose) polymerase (PARP) inhibitors in patients with epithelial ovarian cancer. Therefore, the performance of tumor molecular profiling is currently recommended by international guidelines at initial diagnosis, among other reasons, for the modification of the treatment plan. The investigators' hypothesis was that tumor molecular profiling reveals additional parameters that can improve the predictive and prognostic role of the mere presence of HRR gene mutations. The study aimed to investigate the prognostic and predictive role of clonality of pathogenic variants in HRR genes and/or concurrent pathogenic variants in other clinically relevant genes.
This protocol is designed to provide participants currently benefiting from rucaparib treatment in a Clovis-sponsored clinical study with continued access to treatment for as long as they continue to benefit. Participants in long-term follow-up (LTFU) in a parent study may also enroll in this study for continued data collection, as applicable based on parent study objectives.
EP0057-201 is a Phase 2A/B adaptive design study. Phase 2A will test EP0057 in combination with Olaparib and Phase 2B, the randomised part of the study, will test EP0057 in combination with Olaparib against SOC chemotherapy. When EP0057 is combined with Olaparib, it is envisaged that the combination should improve therapeutic responses in the recurrent ovarian cancer disease setting. EP0057 is an investigational nanoparticle-drug conjugate administered intravenously. The rationale for developing EP0057 is to enable selective entry of EP0057 into tumour tissue and as a result create preferential accumulation of EP0057, and therefore of the payload Camptothecin, to translate into maximum tumour cell killing.