NOTIFy (non-toxic lyophilized field)-FISH for the identification of biological agents by Fluorescence in situ Hybridization.

The rapid and reliable diagnostics of highly pathogenic bacteria under restricted field conditions poses one of the major challenges to medical biodefense, especially since false positive or false negative reports might have far-reaching consequences. Fluorescence in situ hybridization (FISH) has the potential to represent a powerful microscopy-based addition to the existing molecular-based diagnostic toolbox. In this study, we developed a set of FISH-probes for the fast, matrix independent and simultaneous detection of thirteen highly pathogenic bacteria in different environmental and clinical sample matrices. Furthermore, we substituted formamide, a routinely used chemical that is toxic and volatile, by non-toxic urea. This will facilitate the application of FISH under resource limited field laboratory conditions. We demonstrate that hybridizations performed with urea show the same specificity and comparable signal intensities for the FISH-probes used in this study. To further simplify the use of FISH in the field, we lyophilized the reagents needed for FISH. The signal intensities obtained with these lyophilized reagents are comparable to freshly prepared reagents even after storage for a month at room temperature. Finally, we show that by the use of non-toxic lyophilized field (NOTIFy)-FISH, specific detection of microorganisms with simple and easily transportable equipment is possible in the field.

Detection of Coxiella burnetii in heart valve sections by fluorescence in situ hybridization.

PURPOSE: Infective endocarditis is a severe and potentially fatal disease. Nearly a third of all cases remain culture-negative, making a targeted and effective antibiotic therapy of patients challenging. In the past years, fluorescence in situ hybridization (FISH) has proven its value for the diagnosis of infective endocarditis, particularly when it is caused by fastidious bacteria. To increase the number of infective endocarditis causing agents, which can be identified by FISH, we designed and optimized a FISH-probe for the specific detection of Coxiella burnetii in heart valve tissue. METHODOLOGY: Even with specific probes the detection and identification of bacteria can be complicated by the high autofluorescence due to calcification of the analysed tissue. To overcome this problem, we developed a protocol to detect C. burnetii by hybridizing, stripping and reprobing the identical section with different species-specific probes repeatedly.Results/Key findings. The newly designed specific FISH probe and the developed protocol exemplarily allowed us to unequivocally identify C. burnetii in tissue sections of a patient with infective endocarditis. CONCLUSION: This method provides an add-on to existing protocols for the unambiguous diagnosis of bacteria directly within tissues or other difficult tissue samples in cases with small sample size and limited sections.