Production and analysis of a Bacillus subtilis biofilm comprised of vegetative cells and spores using a modified colony biofilm model.

Bacillus subtilis is a spore-forming soil bacterium that is capable of producing robust biofilms. Sporulation can occur in B. subtilis biofilms and it is possible that the spores embedded in the protective matrix could present a significant challenge to disinfecting agents or processes. This article describes a method for the growth and quantification of a reproducible B. subtilis ATCC 35021 biofilm comprised of vegetative cells and spores using a modified colony biofilm model. In this method, membranes were inoculated and incubated for a total of 8 days to promote biofilm formation and subsequent sporulation within the biofilm. Representative samples were taken over the course of the incubation period to evaluate the biofilms using enumerative, microscopic, and spectrometric methods. At various time points, the total numbers of cells and spores were quantified. A Congo red agar (CRA) method was utilized to detect the TasA matrix protein, a primary component of the B. subtilis biofilm matrix. The presence of TasA was also confirmed using mass spectrometry. The biofilm morphologies were correlated to the enumeration data with a variety of correlative imaging techniques: confocal microscopy, scanning electron microscopy (SEM), and transmission electron microscopy (TEM). At the end of the incubation period, the biofilm contained >7 logs total colony forming units with spores comprising approximately 10% of the biofilm. The biofilm generated using this method allows researchers to use a new, more robust challenge for efficacy testing of chemical and physical antimicrobial treatments such as antibiotics, disinfectants, or heat.

Thrombin based gelatin matrix and fibrin sealant mediated clot formation in the presence of clopidogrel.

BACKGROUND: Platelet inhibitors are commonly used to reduce the risk of atherothrombotic events. The aim of this study was to determine the impact of platelet inhibitors, specifically clopidogrel and aspirin, on clot kinetics, strength, and/or structure during the use of thrombin based gelatin matrices and fibrin sealants. METHODS: Blood was collected and heparinized from donors on clopidogrel (and aspirin) and age matched control donors. Blood component analysis, whole blood platelet aggregometry, and activated clotting time (ACT) were used to monitor compliance to therapy and identify any differences between donor groups. Clot kinetics and strength were analyzed using thrombelastography (TEG). Field Emission Scanning Electron Microscopy (FESEM) was used to analyze clot structure. RESULTS: Blood component profiles were similar for both donor groups. Aggregometry indicated that aggregation response to adenosine diphosphate (ADP) for clopidogrel donors was 12% of that for the controls (p = 0.0021), an expected result of clopidogrel induced platelet inhibition. However, blood from both donor groups had an elevated thrombin induced aggregation response. Heparinization of donor blood resulted in similarly elevated ACTs for both donor groups. TEG results indicated similar clot kinetics and strength between clopidogrel and control donor groups for blood alone and when clotting was induced using thrombin based gelatin matrices and fibrin sealants. FESEM images supported TEG findings in that similar morphologies were observed in ex vivo formed clots from both donor groups when thrombin based gelatin matrices and fibrin sealants were used. CONCLUSION: These results suggest that platelet inhibitors do not negatively impact clot kinetics, strength, and structure when clotting is initiated with thrombin based gelatin matrices and fibrin sealants.

Paclitaxel nanosuspensions for targeted chemotherapy - nanosuspension preparation, characterization, and use.

OBJECTIVE: The purpose of this work was to prepare a stable paclitaxel nanosuspension and test it for potential use as a targeted chemotherapeutic. Different particle coatings were employed to assess their impact on cellular uptake in vitro. In vivo work was then performed to demonstrate efficacy in tumor-bearing mouse models. MATERIALS AND METHOD: Paclitaxel nanosuspensions were prepared using a homogenization process and coated with excipients. Surface charge was measured by zeta potential, potency by high-performance liquid chromatography, and solubility using an in-line UV probe. Cellular uptake studies were performed via flow cytometry. In vivo experiments were performed to determine residence time, maximum tolerated dose, and the efficacy of paclitaxel nanosuspensions (Paclitaxel-NS). RESULTS: A stable paclitaxel nanosuspension was prepared and coated with various excipients. Studies in mice showed that the nanosuspension was well-tolerated and at least as effective as the IV Taxol control in prolonging mouse survival in a head and neck cancer model as well as an ovarian cancer model with a lower overall drug dose than the traditional IV administration route. CONCLUSIONS: The paclitaxel nanosuspension is suitable for cellular uptake. The nanosuspension was effective in prolonging life in two separate xenograft orthotopic murine cancer models through two separate routes of administration.

Cell compatibility of fibrin sealants: in vitro study with cells involved in soft tissue repair.

Fibrin sealants can be used to support tissue regeneration or as vehicles for delivery of cells in tissue engineering. Differences in the composition of fibrin sealants, however, could determine the success of such applications. The results presented in this article show clear differences between Fibrin sealant A (FS A) clots and Fibrin sealant B (FS B) clots with respect to their compatibility with primary human cells involved in soft tissue repair. FS A clots, which are characterized by a physiological coarse fibrin structure, promoted attachment, spreading, and proliferation of keratinocytes, fibroblasts, and endothelial cells. In contrast, FS B clots displaying a fine to medium clot structure failed to support spreading of all three cell types. Adhesion of keratinocytes was decreased on FS B clots compared to FS A clots after 3 h incubation, whereas number of attached fibroblasts and endothelial cells was initially comparable between the two fibrin sealants. However, all three cell types proliferated on FS A clots but no sustained proliferation was detected on FS B clots. We further demonstrate that the observed differences between FS A and B clots are partly based upon 1 M sodium chloride extractable constituents, like thrombin, and partly on nonextractable constituents or the fibrin structure. In conclusion, our in vitro results demonstrate that FS A clots serve as a provisional matrix that encourages adhesion and growth of keratinocytes, fibroblasts, and endothelial cells. Therefore, FS A seems to be well suited for applications in tissue engineering.