At Biotechnica, which took place in Hannover on 5-7 October, Saw Instruments launched its Sam5 biosensor instrument for advanced real-time biomolecular interaction and kinetic studies.
The Sam5 is a peerless biosensor that utilises Surface Acoustic Wave technology for the label-free detection of real-time binding and structural events.
Using a proprietary bimodal measurement technique, this platform is able to measure conformational changes in membranes and vesicles, as well as more traditional cellular samples.
The sensor chips integrate five independent sensor elements for simultaneous analysis of different species or parameters and parallel references.
As a result, the Sam5 matches the biosensor needs of a much broader range of researchers than existing systems, while also providing the precision required to drive conventional studies forward.
As part of the European launch, Dr Thomas Gronewold from Saw Instruments will be presenting a snapshot of the Sam5 instrument, with applications data, at the Innovation Forum on 6 October at 2.45-3.10pm, entitled 'Sam5 biosensor - a new solution for simple and robust label-free biomolecular interaction analyses in biotech and academia'.
Saw is also exhibiting at Biotechnica and is running personal hands-on demonstrations of the Sam5.
Surface acoustic wave technology is based on a specific acoustic wave mode and its particularity to propagate confined to the surface of a material.
Each surface has typical inherent properties affecting the wave as it travels across the surface of the material being analysed.
Thus, the nature of the surface in question, and therefore any changes to it, can be assessed by sensors monitoring the behaviour of the wave as it propagates across the surface.
In particular, changes in mass result in alterations to the propagation velocity of the wave, while viscoelastic and conformational characteristics additionally influence wave amplitude.
The technology developed and employed by Saw Instruments is capable of accurately interpreting this information in order to provide real-time readouts, measuring binding and conformational changes in the samples through which the wave passes.
