Plasma temperature during methylene blue/light treatment influences virus inactivation capacity and product quality.

BACKGROUND: Photodynamic treatment using methylene blue (MB) and visible light is in routine use for pathogen inactivation of human plasma in different countries. Ambient and product temperature conditions for human plasma during production may vary between production sites. The influence of different temperature conditions on virus inactivation capacity and plasma quality of the THERAFLEX MB-Plasma procedure was investigated in this study. METHODS: Plasma units equilibrated to 5 ± 2°C, room temperature (22 ± 2°C) or 30 ± 2°C were treated with MB/light and comparatively assessed for the inactivation capacity for three different viruses, concentrations of MB and its photoproducts, activity of various plasma coagulation factors and clotting time. RESULTS: Reduced solubility of the MB pill was observed at 5 ± 2°C. Photocatalytic degradation of MB increased with increasing temperature, and the greatest formation of photoproducts (mainly azure B) occurred at 30 ± 2°C. Inactivation of suid herpesvirus, bovine viral diarrhoea virus and vesicular stomatitis virus was significantly lower at 5 ± 2°C than at higher temperatures. MB/light treatment affected clotting times and the activity of almost all investigated plasma proteins. Factor VIII (-17·7 ± 8·3%, 22 ± 2°C) and fibrinogen (-14·4 ± 16·4%, 22 ± 2°C) showed the highest decreases in activity. Increasing plasma temperatures resulted in greater changes in clotting time and higher losses of plasma coagulation factor activity. CONCLUSIONS: Temperature conditions for THERAFLEX MB-Plasma treatment must be carefully controlled to assure uniform quality of pathogen-reduced plasma in routine production. Inactivation of cooled plasma is not recommended.

Challenge study of the pathogen reduction capacity of the THERAFLEX MB-Plasma technology.

BACKGROUND AND OBJECTIVES: Although most pathogen reduction systems for plasma primarily target viruses, bacterial contamination may also occur. This study aimed to investigate the bacterial reduction capacity of a methylene blue (MB) treatment process and its virus inactivation capacity in lipaemic plasma. MATERIALS AND METHODS: Bacterial concentrations in plasma units spiked with different bacterial strains were measured before and after the following steps of the THERAFLEX MB-Plasma procedure: leucocyte filtration, MB/light treatment and MB filtration. Virus inactivation was investigated for three virus types in non-lipaemic, borderline lipaemic and highly lipaemic plasma. RESULTS: Leucocyte filtration alone efficiently eliminated most of the tested bacteria by more than 4 logs (Staphylococcus epidermidis and Staphylococcus aureus) or to the limit of detection (LOD) (≥ 4.8 logs; Escherichia coli, Bacillus cereus and Klebsiella pneumoniae). MB/light and MB filtration further reduced Staphylococcus epidermidis and Staphylococcus aureus to below the LOD. The small bacterium Brevundimonas diminuta was reduced by 1.7 logs by leucocyte filtration alone, and to below the LOD by additional MB/light treatment and MB filtration (≥ 3.7 logs). Suid herpesvirus 1, bovine viral diarrhoea virus and human immunodeficiency virus 1 were efficiently inactivated by THERAFLEX MB-Plasma, independent of the degree of lipaemia. CONCLUSION: THERAFLEX MB-Plasma efficiently reduces bacteria, mainly via the integrated filtration system. Its virus inactivation capacity is sufficient to compensate for reduced light transparency due to lipaemia.

Colony stimulating factors modulate the transcription of type VIII collagen in vascular smooth muscle cells.

Colony stimulating factors belong to a family of cytokines that regulate proliferation in macrophages and other vascular cell types. They have been implicated in the inflammatory-fibroproliferative response of atherosclerosis. The present study was undertaken to assess the effect of granulocyte-macrophage and macrophage colony stimulating factors on the transcription of type VIII collagen by vascular smooth muscle cells and their potential relevance for the expression of collagen in atherosclerotic lesions. The influence of colony stimulating factors was studied in relation to transforming growth factor beta1, the factor exhibiting the most potent effect on collagen metabolism. Northern blot experiments showed that treatment with both colony stimulating factors and transforming growth factor beta1 transiently stimulated the transcription of type VIII collagen mRNA. Maximal levels were reached after 2 h and 100 pg/ml granulocyte macrophage colony stimulating factor (4-fold), 1 U/ml macrophage colony stimulating factor (4.6-fold) and 1 ng/ml transforming growth factor beta1 (1.6-fold). While overnight treatment with colony stimulating factors stimulated the expression of transforming growth factor beta1 mRNA, short incubations did not influence or downregulate the transcription. In turn, treatment with transforming growth factor beta1 reduced the expression of granulocyte-macrophage and macrophage colony stimulating factor mRNA. The in vitro mRNA expression patterns were directly reflected in the distribution patterns found in intimal thickenings and advanced atherosclerotic lesions. This study demonstrates that colony stimulating factors and transforming growth factor beta1 modulate the transcription of type VIII collagen in vitro. Our data indicate a direct mechanism and exclude a pathway, which is mediated via the stimulation of transforming growth factor beta1 transcription. Our studies further support the hypothesis that colony stimulating factors in concert with transforming growth factor beta1 affect the collagenous composition of the extracellular vascular matrix.

Left-ventricular expression of interleukin-6 messenger-RNA higher in idiopathic dilated than in ischemic cardiomyopathy.

During end-stage heart failure, plasma levels of interleukin-6 (IL6) are elevated. This cytokine exerts a negative inotropic influence on the myocardium. The production site of IL6 is unclear. We examined the hypothesis that IL6 in end-stage heart-failure patients is produced in the myocardium itself and is differentially regulated according to etiology. Cardiac tissue was obtained from 27 patients (idiopathic dilated cardiomyopathy, (DCM) 9/6 m/f, age 46 +/- 14 y; ischemic cardiomyopathy (ICM), 11/1 m/f, age 55 +/- 8 y) at the time of transplantation. The tissue was subjected to IL6 Northern-blot analysis. Signals were quantified by densitometric scanning after normalization to G3 PDH mRNA. Data were compared by Mann-Whitney test between DCM and ICM patients, divided by chamber origin. IL6 transcripts were found in all patients. In DCM, left-ventricular IL6 mRNA expression was higher than in ICM (p = 0.006). Median right-ventricular as well as left- and right-atrial IL6 mRNA expression was not significantly different in both groups. In summary, in end-stage heart failure, IL6 mRNA is consistently expressed in the myocardium. Left-ventricular expression is higher in DCM than in ICM. These data support the concept of a potentially reversible inflammatory component in the etiology of DCM which is more pronounced than in patients with ICM of comparable clinical severity.

Granulocyte-macrophage colony-stimulating factor (GM-CSF) modulates the expression of type VIII collagen mRNA in vascular smooth muscle cells and both are codistributed during atherogenesis.

The expression of granulocyte-macrophage colony-stimulating factor (GM-CSF) and type VIII collagen was studied in human arteries. GM-CSF and type VIII collagen were codistributed in all layers of the walls of nondiseased arteries and during early atherogenesis with up to type V lesions. The number of cells expressing both mRNAs increased during the development of advanced atherosclerotic lesions. Whereas type VIII collagen expression increased further in complicated lesions, GM-CSF was downregulated. During early atherogenesis smooth muscle cells (SMC) and endothelial cells were the principal GM-CSF and type VIII collagen mRNA-expressing cell types. In advanced lesions monocytes/macrophages also expressed the mRNAs. In complicated lesions the number of GM-CSF mRNA-expressing SMC was markedly reduced. In in vitro experiments transforming growth factor-beta1, platelet-derived growth factor, and GM-CSF, but not basic fibroblast growth factor, stimulated the expression of type VIII collagen mRNA by SMC. GM-CSF transiently stimulated type VIII collagen transcription. Thus GM-CSF is a prominent component of the regulatory network influencing collagen metabolism during atherogenesis. By modulating the synthesis of type VIII collagen in SMC, GM-CSF may influence the course of plaque development and may govern processes such as cell movement, plaque stability, and thrombus organization.