Evaluation of a 3D Human Artificial Lymph Node as Test Model for the Assessment of Immunogenicity of Protein Aggregates.

The immunogenicity of protein aggregates has been investigated in numerous studies. Nevertheless, it is still unknown which kind of protein aggregates enhance immunogenicity the most. The ability of the currently used in vitro and in vivo systems regarding their predictability of immunogenicity in humans is often questionable, and results are partially contradictive. In this study, we used a 2D in vitro assay and a complex 3D human artificial lymph node model to predict the immunogenicity of protein aggregates of bevacizumab and adalimumab. The monoclonal antibodies were exposed to different stress conditions such as light, heat, and mechanical stress to trigger the formation of protein aggregates and particles, and samples were analyzed thoroughly. Cells and culture supernatants were harvested and analyzed for dendritic cell marker and cytokines. Our study in the artificial lymph node model revealed that bevacizumab after exposure to heat triggered a TH1- and proinflammatory immune response, whereas no trend of immune responses was seen for adalimumab after exposure to different stress conditions. The human artificial lymph node model represents a new test model for testing the immunogenicity of protein aggregates combining the relevance of a 3D human system with the rather easy handling of an in vitro setup.

Immunological substance testing on human lymphatic micro-organoids in vitro.

Pharmaceutical drugs and compounds used for consumer products may bear the risk of unexpected immuno-toxicological side effects, such as sensitization, allergy, anaphylaxis or immunogenicity. Modern biopharmaceuticals with high potency and target specificity, like antibodies and cytokines need to be tested for their therapeutical doses, their exposition regimens and their immune functionality prior to first-in-man applications. For the latter, existing in vitro tests and animal models do not sufficiently reflect the complexity and specificity of the human immune system. Even novel humanised animal models have limitations in their systemic reactions. Monolayer or suspended cell culture possesses neither tissue functionality nor organ physiology, and also cannot be used for long term culture and experiments. In contrast, solid tissue biopsies, e.g. tonsil preparations of tonsillitis patients typically show inflammatory artefacts and degrade in long term culture due to preparation-induced damage. The construction of tissue-like structures in vitro, so-called "micro-organoids", can overcome these limitations. Key structures of secondary lymphatic organs, e.g. lymph nodes or the spleen are the primary lymphatic follicles and germinal centres, in particular during the "activated state" of an inflammation or infection. To remodel lymphatic follicles, functional and structural cells, e.g. lymphoid cells derived from peripheral blood mononuclear cells (PBMCs) and stromal cells need to be combined with biogenic or artificial matrices and scaffolds to produce a suitable 3D tissue-mimicking environment. Therefore, a unique human lymph node model (HuALN) was designed to operate over several weeks, and allow long term and repeated drug exposure to induce and monitor both cellular and humoral immune responses. Cellular immunity is monitored, for example, by cytokine release patterns; humoral immunity is analysed, for example, by B cell activation, plasma cell formation and antibody secretion profiles (IgM and IgG). Moreover, cellular composition and micro-organoid formation are analysed by flow cytometry, histology and in situ imaging.