Detection of fat embolism in cases with postmortem angiography (PMA) - Preliminary results

Introduction: Pulmonary fat embolism (PFE) can be a cause of death in cases with trauma, during orthopedic surgery and also in non-traumatic conditions, such as burns, pancreatitis, fatty liver or sickle cell disease. As PMA becomes more widespread, it is important to determine how it affects the diagnosis of PFE. Aims: The aim of this study was to determine if the oily contrast liquid used in PMA induces artefactual PFE, if such artefacts differ from original PFE and if PFE can be detected and graded before PMA. Material and methods: Cases of adults without signs of postmortem change and for which an autopsy with angiography was performed were selected for this study. Pulmonary biopsies of each lung were taken before and after the angiography as were fragments of each lung with a twin-edged knife during the autopsy. The samples were examined under the microscope without fixation or staining and after an Oil-Red O staining. PFE was graded according to Falci et al. Results: Non-artefactual (original) PFE was diagnosed in 4 cases on pre-PMA biopsies. As expected, structures with the aspect of PFE were present in all cases after angiography. The microscopical aspect of original and PMA induced PFE was identical. Grading of the PFE according to Falci et al. was depending on the quality of the biopsies. Conclusions: PMA with oily contrast induces artefactual PFE that cannot be visually differentiated from original PFE. Original PFE can however be diagnosed with pre-angiography biopsies. In order to assure the diagnosis and correct grading of PFE, the quality of the biopsy should be checked before PMA with oily contrast.

Fate of TLR-1/TLR-2 agonist functionalised pDNA nanoparticles upon deposition at the human bronchial epithelium in vitro.

BACKGROUND: Plasmid DNA vaccination is a promising approach, but studies in non-human primates and humans failed to achieve protective immunity. To optimise this technology further with focus on pulmonary administration, we developed and evaluated an adjuvant-equipped DNA carrier system based on the biopolymer chitosan. In more detail, the uptake and accompanying immune response of adjuvant Pam3Cys (Toll-like receptor-1/2 agonist) decorated chitosan DNA nanoparticles (NP) were explored by using a three-dimensional (3D) cell culture model of the human epithelial barrier. Pam3Cys functionalised and non-functionalised chitosan DNA NP were sprayed by a microsprayer onto the surface of 3D cell cultures and uptake of NP by epithelial and immune cells (blood monocyte-derived dendritic cells (MDDC) and macrophages (MDM)) was visualised by confocal laser scanning microscopy. In addition, immune activation by TLR pathway was monitored by analysis of interleukin-8 and tumor necrosis factor-α secretions (ELISA). RESULTS: At first, a high uptake rate into antigen-presenting cells (MDDC: 16-17%; MDM: 68-75%) was obtained. Although no significant difference in uptake patterns was observed for Pam3Cys adjuvant functionalised and non-functionalised DNA NP, ELISA of interleukin-8 and tumor necrosis factor-α demonstrated clearly that Pam3Cys functionalisation elicited an overall higher immune response with the ranking of Pam3Cys chitosan DNA NPâeuro0/00>âeuro0/00chitosan DNA NPâeuro0/00=âeuro0/00DNA unloaded chitosan NPâeuro0/00>âeuro0/00control (culture medium). CONCLUSIONS: Chitosan-based DNA delivery enables uptake into abluminal MDDC, which are the most immune competent cells in the human lung for the induction of antigen-specific immunity. In addition, Pam3Cys adjuvant functionalisation of chitosan DNA NP enhances significantly an environment favoring recruitment of immune cells together with a Th1 associated (cellular) immune response due to elevated IL-8 and TNF-α levels. The latter renders this DNA delivery approach attractive for potential DNA vaccination against intracellular pathogens in the lung (e.g., Mycobacterium tuberculosis or influenza virus).