© 2020 Elsevier Inc. All rights reserved.The interaction strength between CD8+ T cells' TCR and cognate peptide-MHC (pMHC) impacts on the CD8+ T cell response against pathogens and tumors (Martinez-Usatorre, Donda, Zehn, & Romero, 2018; Zehn, Lee, & Bevan, 2009). CD8+ T cell responses against tumors are characterized by the presence of low affinity CD8+ T cells specific for nonmutated tumor associated self-antigens (TAA) and potentially high affinity tumor specific CD8+ T cells recognizing mutated self-antigens (Gros et al., 2016; Kvistborg et al., 2012; McMahan & Slansky, 2007). High affinity T cells display enhanced survival, expansion capacity and tumor control (Martinez-Usatorre et al., 2018; Schmid et al., 2010).  https://www.selleckchem.com/products/vt107.html  In fact, recent clinical trials using neoantigen tumor vaccines showed prolonged progression free survival in melanoma patients (Ott et al., 2017; Sahin et al., 2017), while only modest clinical efficacy was obtained with TAA vaccines (Romero et al., 2016). However, the highly individual nature of neoantigens constitutes a major technical and economical hurdle for routine clinical application. Thus, the characterization of TAA-specific CD8+ T cell responses may reveal new strategies to enhance their anti-tumor properties. In parallel, the identification of high affinity antigens and CD8+ T cells may be essential to design effective tumor vaccines and adoptive cell transfer therapies. Therefore, in this chapter, we describe how to generate tumor cell lines with stable expression of affinity-ranged antigens and methods to assess T-cell affinity. © 2020 Elsevier Inc. All rights reserved.Understanding the interactions between immune and cancer cells occurring within the tumor microenvironment is a prerequisite for successful and personalized anti-cancer therapies. Microfluidic devices, coupled to advanced microscopy systems and automated analytical tools, can represent an innovative approach for high-throughput investigations on immune cell-cancer interactions. In order to study such interactions and to evaluate how therapeutic agents can affect this crosstalk, we employed two ad hoc fabricated microfluidic platforms reproducing advanced 2D or 3D tumor immune microenvironments. In the first type of chip, we confronted the capacity of tumor cells embedded in Matrigel containing one drug or Matrigel containing a combination of two drugs to attract differentially immune cells, by fluorescence microscopy analyses. In the second chip, we investigated the migratory/interaction response of naïve immune cells to danger signals emanated from tumor cells treated with an immunogenic drug, by time-lapse microscopy and automated tracking analysis. We demonstrate that microfluidic platforms and their associated high-throughput computed analyses can represent versatile and smart systems to (i) monitor and quantify the recruitment and interactions of the immune cells with cancer in a controlled environment, (ii) evaluate the immunogenic effects of anti-cancer therapeutic agents and (iii) evaluate the immunogenic efficacy of combinatorial regimens with respect to single agents. © 2020 Elsevier Inc. All rights reserved.Critical to the advancement of tumor immunotherapy is the reliable identification of responders and the quantification of the tumor-specific immune response elicited by treatments. In this regard, Enzyme-Linked Immunospot assay (ELISpot) is an ideal monitoring technique due to its high sensitivity, ease of execution and cost-effectiveness. Originally developed for the enumeration of B cells secreting antigen-specific antibodies, ELISpot assay has been adapted to detect and quantify cytokine-secreting immune cells present at low frequency in a variety of biological samples, including blood, in response to antigen-specific stimuli. The above-mentioned features emphasize the role of ELISpot as valuable assay for translational research and clinical applications. In the present chapter, we will focus on the use of ELISpot assay for monitoring the tumor-specific effector responses induced by different treatments in preclinical models and will provide some protocols and technical hints for its application. © 2020 Elsevier Inc. All rights reserved.Monoclonal antibody-based therapies are increasingly being used to treat cancer. Some mediate their therapeutic effects through modifying the function of immune cells globally, while others bind directly to tumor cells and can recruit immune effector cells through their Fc regions. As new direct-binding agents are developed, having the ability to test their Fc-mediated functions in a high-throughput manner is important for selecting antibodies with immune effector properties. Here, using monoclonal anti-CD20 antibody (rituximab) as an example and the CD20+ Raji cell line as tumor target, we describe flow cytometry-based assays for determining an antibody's capacity for mediating antibody-dependent cellular cytotoxicity (ADCC), antibody-dependent cellular phagocytosis (ADCP) and complement-dependent cytotoxicity (CDC). These assays are sensitive, reliable, affordable and avoid the use of radioactivity. © 2020 Elsevier Inc. All rights reserved.APCs play a key role at initiating adaptive immune responses by presenting antigens to lymphocytes and DCs are professional APCs. It is critical to understand the differential antigen capture and presentation ability of different DC subsets, which is important for DC-targeted immunotherapy. In this section, we give a brief introduction to different antigen presentation pathways and introduce the key concept of cross-presentation, the major antigen presentation pathway used for anti-viral and anti-tumoral immune responses. CD205, a DC restricted receptor, is highly expressed on certain DCs subsets. We find CD205-mediated antigen uptake to be a useful model for studying antigen uptake and defects. These methods provide an introduction to CD205-mediated pre-clinical delivery of antigens to cross-presenting DCs, which can be adapted to the study of targeting to multiple receptors and other C-type lectins. This is a promising strategy to detect the antigen capture capacity and to study the key players orchestrating tolerance and immunity ex vivo.