2381/44209 WY Chung WY Chung JJ Wanford JJ Wanford R Kumar R Kumar JD Isherwood JD Isherwood RD Haigh RD Haigh MR Oggioni MR Oggioni AR Dennison AR Dennison G Ercoli G Ercoli An ex vivo porcine spleen perfusion as a model of bacterial sepsis. University of Leicester 2019 IR content 2019-05-23 10:28:39 Journal contribution https://figshare.le.ac.uk/articles/journal_contribution/An_ex_vivo_porcine_spleen_perfusion_as_a_model_of_bacterial_sepsis_/10215338 An ex vivo, porcine spleen perfusion model was established to study the early events occurring in the spleen prior to the onset of bacterial sepsis, using organs retrieved from animals slaughtered for food production. Porcine spleens were harvested from adult pigs and connected to a normothermic extracorporeal perfusion circuit. A constant perfusion of heparinized blood was performed for 6 hours. After injection of Streptococcus pneumoniae to the circuit serial samples of both blood and spleen biopsies were collected and analysed. Functionality of the perfused organs was assessed by monitoring the blood-gas parameters, flow rate and filtering capability of the organ. Interestingly, we observed full clearance of bacteria from the blood and an increase in bacterial counts in the spleen. Classical histology and immunohistochemistry on biopsies also confirmed no major damages in the organ architecture and changes in the immune cell distribution, other than the presence of clusters of pneumococci. A time-course study confirmed that each focus of infection derived from the replication of single pneumococcal cells within splenic macrophages. The model proposed - in line with the 3Rs principles - has utility in the replacement of experimental animals in infection research. Murine models are prevalently used to study pneumococcal infections, but are often not predictive for humans due to substantial differences in the immune systems of the two species. This model is designed to overcome these limitations, since porcine immunology and splenic architecture in particular, closely resemble those of humans.