Advancements in minimally invasive image-guided liver therapies

This thesis is a contribution to the fight against cancer. It focuses on patients with hepatic malignancies. Interventional oncology (IO) is a rapidly evolving sub-speciality of interventional radiology with an increasing role in the management of cancer patients. Over the past two decades interventional radiologists together with scientists have ridding the tidal wave of technological innovation to introduce multiple novel cancer treatments. IO procedures are minimally invasive, targeted therapies that are associated with low complication rates and short hospital admissions. Such therapies offer clear advantages over surgical procedures and intense chemotherapeutic regimes that put a larger burden on both the health care budget and patients. In this thesis several novel minimally invasive therapies are investigated. PART I focuses on image-guided percutaneous RFA. PART II discusses transarterial liver therapies, such as transarterial chemoembolisation, radioembolisation and percutaneous hepatic perfusion. PART III investigates ways to improve the management of patients that undergo IO procedures.LUMC / Geneeskund

Vandetanib-eluting radiopaque beads and stereotactic body radiotherapy in the treatment of liver cancers

Background: Current treatment options for unresectable hepatocellular carcinoma (HCC) and colorectal liver metastases (mCRC) include transarterial chemoembolisation (TACE) and stereotactic body radiotherapy (SBRT). The objectives of this project were: 1. To assess a novel drug-eluting bead for TACE / 2. To report on the safety and efficacy of SBRT in HCC / 3. To assess the feasibility of using radiopaque beads as fiducial markers for SBRT / Methods: In Part 1, a first-in-human trial was performed in patients with HCC and mCRC using a novel vandetanib-eluting radiopaque bead, BTG-002814. Primary trial endpoints were safety/tolerability and the concentrations of vandetanib and its major metabolite in plasma and resected tissue. Biomarker studies included blood cytokines and perfusion imaging parameters. In Part 2, the efficacy of SBRT was explored in a retrospective study of 31 patients with HCC tumours ≤5 cm and in a phase II study of 13 patients with larger tumours. In Part 3 the feasibility of using radiopaque beads as fiducial markers for SBRT was investigated. / Results: BTG-002814 was shown to have a satisfactory safety profile in 8 patients. Vandetanib was present in the plasma of all patients 12 days post-TACE, and present in resected liver tissue up to 32 days post-treatment. There were no significant changes in perfusion parameters. Blood biomarker studies showed increases in leptin, osteopontin and sTie2. SBRT offered 1-year local control rates of 94% in small HCCs and 92% in larger tumours. Radiopaque beads were visible on 4D-CT and CBCT images in all 8 cases and matching successfully performed. / Conclusions: The safety profile and pharmacokinetic characteristics for this novel technology are adequate to proceed to a Phase I/II trial. SBRT is an effective local treatment for HCC. The role of radiopaque beads as fiducial markers is feasible and warrants further exploration as a clinical trial of TACE with SBRT

3D Imaging for Planning of Minimally Invasive Surgical Procedures

Novel minimally invasive surgeries are used for treating cardiovascular diseases and are performed under 2D fluoroscopic guidance with a C-arm system. 3D multidetector row computed tomography (MDCT) images are routinely used for preprocedural planning and postprocedural follow-up. For preprocedural planning, the ability to integrate the MDCT with fluoroscopic images for intraprocedural guidance is of clinical interest. Registration may be facilitated by rotating the C-arm to acquire 3D C-arm CT images. This dissertation describes the development of optimal scan and contrast parameters for C-arm CT in 6 swine. A 5-s ungated C-arm CT acquisition during rapid ventricular pacing with aortic root injection using minimal contrast (36 mL), producing high attenuation (1226), few artifacts (2.0), and measurements similar to those from MDCT (p\u3e0.05) was determined optimal. 3D MDCT and C-arm CT images were registered to overlay the aortic structures from MDCT onto fluoroscopic images for guidance in placing the prosthesis. This work also describes the development of a methodology to develop power equation (R2\u3e0.998) for estimating dose with C-arm CT based on applied tube voltage. Application in 10 patients yielded 5.48┬▒177 2.02 mGy indicating minimal radiation burden. For postprocedural follow-up, combinations of non-contrast, arterial, venous single energy CT (SECT) scans are used to monitor patients at multiple time intervals resulting in high cumulative radiation dose. Employing a single dual-energy CT (DECT) scan to replace two SECT scans can reduce dose. This work focuses on evaluating the feasibility of DECT imaging in the arterial phase. The replacement of non-contrast and arterial SECT acquisitions with one arterial DECT acquisition in 30 patients allowed generation of virtual non-contrast (VNC) images with 31 dose savings. Aortic luminal attenuation in VNC (32┬▒177 2 HU) was similar to true non-contrast images (35┬▒177 4 HU) indicating presence of unattenuated blood. To improve discrimination between c

Hepatocellular Carcinoma

Hepatocellular carcinoma (HCC) represents one of the most significant global health issues, given its high prevalence and the challenging nature and physiology of the liver and hepatic surgery, in its many forms. This means that the most appropriate management for HCC should incorporate a multidisciplinary approach, combining the expertise from several different specialties. This book showcases the various steps in the development, diagnosis, staging, and management of HCC and provides views and thoughts from true experts in the field. As such, it is a useful resource for any physician or surgeon, whether training or practicing, who is interested in caring for patients with HCC

CT Scanning

Since its introduction in 1972, X-ray computed tomography (CT) has evolved into an essential diagnostic imaging tool for a continually increasing variety of clinical applications. The goal of this book was not simply to summarize currently available CT imaging techniques but also to provide clinical perspectives, advances in hybrid technologies, new applications other than medicine and an outlook on future developments. Major experts in this growing field contributed to this book, which is geared to radiologists, orthopedic surgeons, engineers, and clinical and basic researchers. We believe that CT scanning is an effective and essential tools in treatment planning, basic understanding of physiology, and and tackling the ever-increasing challenge of diagnosis in our society

3D Imaging for Planning of Minimally Invasive Surgical Procedures

Novel minimally invasive surgeries are used for treating cardiovascular diseases and are performed under 2D fluoroscopic guidance with a C-arm system. 3D multidetector row computed tomography (MDCT) images are routinely used for preprocedural planning and postprocedural follow-up. For preprocedural planning, the ability to integrate the MDCT with fluoroscopic images for intraprocedural guidance is of clinical interest. Registration may be facilitated by rotating the C-arm to acquire 3D C-arm CT images. This dissertation describes the development of optimal scan and contrast parameters for C-arm CT in 6 swine. A 5-s ungated C-arm CT acquisition during rapid ventricular pacing with aortic root injection using minimal contrast (36 mL), producing high attenuation (1226), few artifacts (2.0), and measurements similar to those from MDCT (p\u3e0.05) was determined optimal. 3D MDCT and C-arm CT images were registered to overlay the aortic structures from MDCT onto fluoroscopic images for guidance in placing the prosthesis. This work also describes the development of a methodology to develop power equation (R2\u3e0.998) for estimating dose with C-arm CT based on applied tube voltage. Application in 10 patients yielded 5.48┬▒177 2.02 mGy indicating minimal radiation burden. For postprocedural follow-up, combinations of non-contrast, arterial, venous single energy CT (SECT) scans are used to monitor patients at multiple time intervals resulting in high cumulative radiation dose. Employing a single dual-energy CT (DECT) scan to replace two SECT scans can reduce dose. This work focuses on evaluating the feasibility of DECT imaging in the arterial phase. The replacement of non-contrast and arterial SECT acquisitions with one arterial DECT acquisition in 30 patients allowed generation of virtual non-contrast (VNC) images with 31 dose savings. Aortic luminal attenuation in VNC (32┬▒177 2 HU) was similar to true non-contrast images (35┬▒177 4 HU) indicating presence of unattenuated blood. To improve discrimination between c