Fluorescence Imaging of Adalimumab-680LT and Risankizumab-800CW in Inflammatory Bowel Disease (VOYAGER)

Inflammatory bowel diseases (IBD) are chronic relapsing inflammatory disorders of the gastrointestinal tract affecting 2.5 million patients in Europe alone. The majority of newly diagnosed patients are in adolescence or early adulthood and in the midst of their family life, career, and social development.

IBD comes with significant morbidity and complex treatment strategies and is associated with a high social burden and medical costs. Besides other factors, the pathogenesis of IBD is attributed to proinflammatory cytokine tumor necrosis factor α (TNFα) and Interleukin 23 (IL-23). Adalimumab, a human monoclonal anti-TNF antibody, and risankizumab, a humanized monoclonal anti-IL-23 antibody, are used to treat patients with moderate to severely active IBD. However, IBD patients often only partially respond to such biological immunomodulating therapies, resulting in high primary nonresponse (30-60%) and loss of response over time (48-58%). The investigators are currently missing reliable tools for response prediction because the limitations of current technologies do not allow the visualization of the molecular phenotype or heterogeneity within patients. Therefore, patients are potentially exposed to a non-effective treatment and its potential side effects while clinical deterioration is ongoing. In addition, it remains completely unknown for most biologicals used for IBD therapy whether they reach their actual targets in the tissue and if a sufficient local concentration is present to achieve treatment response. To develop a predictive tool for assessment of therapeutic (non-)response to patients and gain insights into local drug concentrations in individual patients before initiating anti-TNF or anti-IL23 therapy, the University Medical Center Groningen (UMCG), fluorescently labeled adalimumab (adalimumab-680LT) and risankizumab (risankizumab-800CW) to visualize and quantify the labeled drugs in diseased tissue with dedicated optical fluorescence imaging systems. In previous studies, the investigators have proven that those tracers bind to TNFα/IL23 in the mucosa after intravenous injection and that the investigators can investigate the drug distribution in vivo due to the colocalization of the fluorescently labeled compound. The aim of this follow-up study is to assess the feasibility of simultaneous dual wavelength imaging of adalimumab-680LT and risankizumab-800CW at baseline and evaluate target saturation after at least 14 weeks of adalimumab or risankizumab therapy. The investigators will also use in vivo and ex vivo fluorescence molecular imaging (FMI) to visualize tracer target cells and the patient's molecular phenotype for potential treatment response prediction in IBD patients in the future.

The investigators will determine the feasibility of dual wavelengths molecular fluorescence imaging using the GMPproduced near-infrared fluorescent tracers adalimumab-680LT and risankizumab-800CW for visualizing medicine distribution in and ex vivo IBD patients with dedicated fluorescence imaging systems.

Furthermore, the investigators will evaluate TNF and IL23 target saturation after 14 weeks of adalimumab or risankizumab therapy and characterize the tissue microenvironment where the drug is abundant and identify potential drug target cells.