Implants improves the quality of life
Modern medicine has developed various implants to replace missing anatomical structure or biological function: joint prostheses, internal fixation devices, vascular prostheses, cardiac pacemakers and defibrillators, dental implants, neurosurgical shunts and breast implants.
New devices are improved and optimized with regard to biocompatibility and functionality.
Biofilm infections– a challenge of modern medicine
Formation of biofilm on implant surface
With growing use of implants, modern medicine is facing an increasing risk of infections. Microorganisms on implant surface form biofilms, what makes them difficult to detect by conventional methods such as periprosthetic tissue cultures. For successful treatment of these infections accurate microbiological diagnosis is crucial. Such biofilms consist of an extracellular matrix of polymerized polysaccharides, in which bacteria are embedded.
Bacteria in biofilm resist antibiotics and defense system
The microorganisms in biofilm are transformed in low metabolic, stationary growth state. Over weeks to months, depending on the type of microorganism, implant material and host, a complex three-dimensional structure develops, which consists of nutrition channels and rudimentary communication system resembling multicellular organism.
Free-living (planktonic) bacteria are killed by antibiotics and the host defense system, while adherent (biofilm) bacteria can survive and persist in the extracellular matrix of the biofilm.
Find out more in the data sheet [626 KB].
Sonication – a new diagnostic method
Sonication removes more than 99.9 % of the biofilm bacteria from the surface
After removal in the operating room, implants are placed in the air-tight container and transported to the microbiological laboratory. After addition of Ringer’s solution, the implant is processed by vortexing (30 seconds) and sonication (1 minute) to dislodge (planktonize) microorganism into the surrounding fluid (sonicate). The sonication fluid is cultured on aerobic and anaerobic agar plates and inoculated in broth media.
Principle of sonication
High acoustic intensity of conventional ultrasound baths kills microorganisms (especially gram-negative and anaerobic bacteria). Sonication in the specially designed ultrasound bath BactoSonic® uses low frequency and low intensity ultrasound at the threshold of microbubble formation (cavitation). Due to micro-currents of sonication fluid, shear forces and oscillating cavitation bubbles biofilm is removed and the bacteria are disaggregated.
The resulting cavitation energy is reduced to the level, that no significant cell destruction occurs, enabling culture of viable microorganisms.
Advantages of sonication
Sonication detects bacteria up to 10,000 times compared to periprosthetic tissue cultures
• High accuracy
With low-intensity sonication, microorganisms are dislodged from the implant but not killed, enabling high sensitivity of conventional cultures (Fig. 4).
Particularly difficult to detect microorganisms (including small-colony variants), individual morphotypes and mixed infections can be better detected. The sensitivity is particularly improved in patients receiving previous antibiotics, due to better survival of bacteria in biofilm. Ultrasound reaches through surrounding fluid the whole implant surface, which is associated with high specificity.
• Rapid result
Sonication increases microbial growth by inducing micro-currents in the sonication fluid, thereby shortening the microbial detection time.
• Quantitative biofilm assessment
Since bacteria survive, but not replicate in the sonication fluid, quantitative assessment of removed biofilm is possible. The microbial density is expressed as number of colony-forming units (CFU) per ml of sonication fluid.
• Additional investigations
The sonication fluid contains high density of bacteria, making it suitable for further microbial (e.g. PCR, MALDI-TOF, microcalorimetry) and immunological analyses (e.g. determination of biomarkers, gene expression).