View clinical trials related to Liver Cancer.
Filter by:Associating liver partition and portal vein ligation for staged hepatectomy (ALPPS) is a new surgical procedure that induces rapid liver regeneration in patients with small liver remnant planning for major liver resection. It is a two-staged operation with stage I including portal vein ligation and splitting the right liver away from the left liver. After stage I, the left liver will undergo rapid liver regeneration and the stage II operation can be performed at 7-10 days after stage I operation when the liver remnant reaches an adequate size. In stage II operation, the right liver that contains the tumor is then removed. This surgical procedure was incepted in Germany in 2013 and was later started in Queen Mary Hospital in Hong Kong for the first time in December 2015. The initial indication was mainly for colorectal liver metastasis but due to the relatively high incidence of hepatocellular carcinoma in Hong Kong, HBP surgery team of Queen Mary Hospital has transferred this procedure to be applied for hepatitis-related hepatocellular carcinoma and so far, the centre has cumulated one of the largest single-center experience in the literature. Nonetheless, the usual approach for ALPPS involved open surgery and induced substantial surgical stress to the patient, especially after stage I operation. With the advent of minimally invasive liver surgery in recent years, the team has successfully applied laparoscopic surgery to ALPPS in 2019. Despite the advancement in laparoscopic surgical skills that rendered laparoscopic ALPPS feasible, there is scarcity of data in the literature to evaluate its outcome in comparison with open ALPPS with regard to perioperative recovery and liver regeneration. Hence, the aim of this project is to evaluate the short-term clinical outcomes of laparoscopic ALPPS and the impact of laparoscopy on liver remnant regeneration after ALPPS in a prospective randomised clinical trial setting.
This is an open-label, dose escalation, multi-center, Phase I/II clinical trial aimed at assessing the safety and preliminary efficacy of an investigational ARTEMIS® ECT204 T-cell therapy. The trial is suitable for adult subjects (≥ 18 years of age) diagnosed with GPC3-positive HCC, who have failed or not tolerated at least two (2) different anti-HCC systemic agents. Phase I has concluded and a Recommended Phase II Dose (RP2D) has been determined. We are now conducting Phase II to further confirm the safety profile of ECT204 and evaluate its efficacy.
Liver cancer is the sixth most commonly diagnosed cancer and the fourth leading cause of cancer death worldwide. It is the 3rd most common cause of cancer death in Hong Kong. The five-year survival rates of liver cancer differ greatly with disease staging, ranging from 91.5% in early-stage to 11% in late-stage. The early and accurate diagnosis of liver cancer is paramount in improving cancer survival. Liver cancer is diagnosed radiologically via cross sectional imaging, e.g. computed tomography (CT), without the routine use of liver biopsy. However, with current internationally-recommended radiological reporting methods, up to 49% of liver lesions may be inconclusive, resulting in repeated scans and a delay in diagnosis and treatment. An artificial intelligence (AI) algorithm that that can accurately diagnosed liver cancer has been developed. Based on an interim analysis, the algorithm achieved a high diagnostic accuracy. The AI algorithm is now ready for implementation. This study aims to prospective validate this AI algorithm in comparison with the current standard of radiological reporting in a randomized manner in the at-risk population undergoing triphasic contrast CT. This research project is totally independent and separated from the actual clinical reporting of the CT scan by the duty radiologist. The primary study outcome is the diagnostic accuracy of liver cancer, which will be unbiasedly based on a composite clinical reference standard.
Tumor infiltration lymphocytes (TILs) have been harvested from advanced cancer patients and constructed to knockout PD1 gene and express scFvs against both PD1 and CTALA4 and CARs against various antigens, followed by transfusion into the patients. The safety, tolerance, and preliminary clinical efficacy of the TILs will be evaluated.
The primary objective of this study, DELFI-L101, is to train and test classifiers for lung cancer detection using the DELFI assay and other biomarker and clinical features.
This study is aimed at assessing the effectiveness of a novel liver specific nerve block in improving pain control during painful liver interventional radiology procedures including liver tumoral ablation and trans arterial chemoembolization, two procedures aimed at controlling liver tumors, but that can be associated with significant pain. This novel hepatic specific nerve block was designed by us and initial retrospective results suggests it might help in controlling such liver procedural derived pain. The study was designed to compare the liver block to a sham procedure in a blinded context and to follow the participants over three days post-procedure to asses for pain levels.
Radiological response after trans arterial chemoembolization (TACE) is classified according to Modified Response Evaluation Criteria in Solid Tumors (mRECIST) to: complete response (CR) (disappearance of arterial enhancement), partial response (PR) ( at least a 30% decrease in the sum of diameters of viable enhancement), progressive disease (PD) (an increase of at least 20% in the sum of the diameters of viable enhancement, or appearance of new lesions), and stable disease (any cases that do not qualify for either partial response or progressive disease
Thromboprophylaxis for liver surgery can be commenced either preoperatively or postoperatively. Despite a clear trade-off between thrombosis and bleeding in liver surgery patients, there is no international consensus when thrombosis prophylaxis should be commenced in patients undergoing liver surgery. As far as we know, there are no prospective randomized trials in this field, and current guidelines are unfortunately based on very low quality evidence, that is, a few retrospective studies and expert opinion. Both American and European thromboprophylaxis guidelines for abdominal cancer surgery support the preoperative initiation of thromboprophylaxis, but these guidelines do not specifically address the increased bleeding risk associated with liver surgery. On the contrary, Dutch guidelines recommend postoperative thromboprophylaxis only, because of lack of evidence for preoperative thromboprophylaxis. Traditionally, many liver surgery units have been reluctant in using preoperative thromboprophylaxis due to the potentially increased risk of bleeding complications. Enhanced Recovery After Surgery (ERAS) Society Guidelines recommend preoperative thromboprophylaxis in liver surgery, but the guidelines provide no supporting evidence for this recommendation. Overall, the amount of evidence is scarce and somewhat contradictory in this clinically relevant field of thromboprophylaxis in liver surgery. The aim of this study is to compare pre- and postoperatively initiated thromboprophylaxis regimens in liver surgery in a randomized controlled trial.
Liver resection remains the only curative option for primary or metastatic liver cancer, but a more accurate prediction of post-hepatectomy liver failure (PHLF) is needed to further reduce morbidity and mortality and to extend the indication to a wider patient population. Magnetic resonance Imaging (MRI) is a promising new source of liver function tests as it can provide segmental function alongside measurements of perfusion, tissue structure and standard morphological assessment. The primary aim of HEPARIM is to determine if quantitative MRI biomarkers of liver function and perfusion can improve predictions of post-hepatectomy liver function, as measured by an indocyanine green (ICG) liver function test. Secondary aims is to validate the MRI measurements of liver function against ICG. HEPARIM is an observational cohort study recruiting patients referred locally for a one- or two-stage liver resection of 2 segments or more. Before surgery, all participants will undergo an ICG liver function test and a Dynamic Gadoxetate-enhanced (DGE) MRI scan of the liver. The ICG test will be repeated at one day after surgery. The Gadoxetate Clearance (GC) of the future liver remnant (FLR-GC) will be determined from the DGE-MRI data and correlated to the post-operative ICG R15 as primary outcome measure. Preoperative ICG R15 will be correlated against GC of the whole liver (WL-GC) to address the secondary objective. In patients that undergo a staged hepatectomy, an additional MRI and ICG test will be performed before the first stage to assess its effect on volumetric and functional growth of the FLR. Additional pre- and postoperative data will be collected from medical records including demographics and medical histories, biochemistry, pathology and radiology reports, and any long-term outcome data collected in the 90-day follow-up visit. These data will be used in a multi-variate analysis to determine which preoperative biomarkers are most predictive of immediate and long-term outcomes, to identify the added value of functional MRI over routine clinical markers, and to derive a multi-variate prediction model that can be validated in future studies.
The purpose of this study is to develop new ways to make medical images of the lungs and liver of adults using a technique called four-dimensional magnetic resonance imaging (4D-MRI). This technique produces three-dimensional movies of the inside of the chest and abdomen while the patient is breathing. (The fourth dimension is time!) This new way of medical imaging is being developed to help cancer patients undergoing radiation therapy. Radiation therapy is used to treat cancerous tumors. For radiation therapy to be effective, the precise size, shape, and location of the tumor within the body must be known. A particular difficulty for radiation treatment of lung and liver cancer is that the tumor moves during treatment because the patient is breathing. Therefore, tumor motion must also be incorporated into the treatment plan. This study aims to improve radiation treatment planning through better targeting and dose estimation based on 4D-MRI. Before this new imaging method can be used for radiation treatment planning, it must be tested in living, breathing volunteers.