The PowerMAG LAB and PowerMAG EEG stimulators from Mag and More, GmbH are suited to a wide range of research applications. These repetitive magnetic stimulators meet all expectations of quality and sophistication for an advanced research device. PowerMAG systems are highly configurable, allowing us to provide a system with just the features you need, whether your application demands a lot or just a little. We not only provide a variety of rTMS simulators with all the relevant accessories, but we also provide innovative solutions for 3D neuronavigation.
• ppTMS short interval (SI), and long interval (LI)
• Quattro pulse stimulation (QPS)
• High power & high frequency protocols
PowerMAG LAB: HIGH PERFORMANCE AT HIGH FREQUENCIES
The PowerMAG LAB represents the top-class in TMS stimulators. It is able to generate burst of pulses up to 100 Hz with constant intensities by recharging between pulses. It also has an impressive maximum pulse frequency of 100 Hz at 70% intensity, making this stimulating device a perfect choice for the latest stimulation protocols, such as theta burst stimulation.
PowerMAG EEG: YOUR ULTIMATE TMS RESEARCH TOOL
The PowerMAG EEG was specially developed for the high-end research user who needs to stimulate while recording EEG concurrently. Powerful high-frequency TMS (including Theta Burst Stimulation) as well as high-precise single pulse and paired pulse protocols are available in one standalone device. In addition to the application areas above, the PowerMAG EEG systems are suitable for online TMS & EEG.
NeurOne EEG system (2)
Maybe. There is no way the EEG system can harm the TMS system, but there are some TMS systems that are essentially useless with some EEG systems. You need a a suitable combination of features in each to be successful at all in using TMS with EEG.
- Coils designed specifically for use with EEG will have a cable that exits the coil tangential to the head surface so that the coil does not pass close by EEG electrodes and cables.
- A coil to be used with EEG should be passively cooled, since active cooling by means of a fan will induce electromagnetic interference in the EEG.
- The TMS recharge mechanism should be designed to avoid inducing electromagnetic artifacts in the EEG.
- The TMS system should be shielded so that no more than 3 milligauss of electromagnetic interference from the TMS system’s power supply reaches the electrodes and cables.
- The TMS system should be able to produce a TMS pulse in response to an input trigger with a low and predictable latency. Long, but especially unpredictable latency in responding to an input trigger will result in TMS artifacts that are difficult to impossible to remove from the EEG.
Aside from attributes of the TMS system, there are also important considerations regarding the EEG system in this relationship. See the other FAQ entry on that topic.
No. There are a few special attributes that are required and others that are desirable.
- Inputs should be protected so that they are not damaged by the TMS pulse
- Frequency response on all channels should be from DC on the low end, since AC coupled inputs will “ring” when presented with a large voltage transient like the TMS artifact
- Electrodes should have a low-profile so that the TMS coil can be placed as near the head as possible, maximizing penetration depth and current delivery
- It is important for the EEG system to be able to trigger the TMS system at precisely the same phase with respect to the EEG samples each time a stimulus is delivered. This will improve the performance of artifact removal algorithms
Aside from these attributes of the EEG system, there are also important considerations regarding the TMS system in this relationship. See the other FAQ entry on that topic.