Navigated and Robotized Transcranial Magnetic
     Stimulation based on 3D Laser Scans

        Lars Richter1,2 , Ralf Bruder1 , Peter Trillenberg3 , Achim Schweikard1
           1
           Institute for Robotics and Cognitive Systems, University of Lübeck
2
    Graduate School for Computing in Medicine and Life Sciences, University of Lübeck
                   3
                     Departement for Neurology, University of Lübeck
                             richter@rob.uni-luebeck.de



         Abstract. Navigated and robotized Transcranial Magnetic Stimulation
         (TMS) is advancing forward in research and treatment. MRI-scans or
         other medical image data are typically used as navigation source. Unfor-
         tunately, scanning time is always short and expensive. For many TMS-
         applications the underlying brain topology is not necessarily needed.
         Therefore, we generate the subject’s head contour for a precise stimula-
         tion from 3D laser scans. We use the PowerCrust algorithm generating
         a smooth contour from laser surface points. The mean error found was
         0.289 with an RMS error of 0.358 mm and a maximum error of 0.984 mm
         comparing MRI-scan to laser scan for a head phantom . Currently, we are
         working successfully with head contours based on 3D laser scans for two
         ongoing TMS studies. During these TMS-experiments, the overall error
         found for the robotized TMS system using laser scans was < 5 mm. With
         new and faster laser technologies, it will be possible to use laser scans as
         navigation source and for direct head tracking during stimulation when
         scanner become real time capable.


1      Introduction
The aim of transcranial magnetic stimulation (TMS) is to stimulate the brain
non-invasively and painlessly using a magnetic coil on top of the patient’s head.
Besides usage as a diagnostic tool, TMS is used as a treatment attempt in dif-
ferent neurological diseases, e.g. depression, chronic tinnitus or chronic pain [1].
For TMS, navigated stimulation has become state-of-the-art, at least in research,
and is available in many TMS systems [2]. Mostly, (f)MRI-scans are used as
navigation source. Unfortunately, MRI-scans are expansive and scanning time is
often short. Robotized systems for TMS are advancing forward and are claimed
more and more for exact stimulation [3]. For the robotized TMS system, a mag-
netic coil is placed directly on top of a patient’s head by the robot being able to
induce an electric current in a predefined region of the brain [4].
    For treatment attempts of neurological disorders like tinnitus or schizophre-
nia, the stimulation point is selected mostly based on fMRI information. More-
over, for brain mapping purposes the underlying brain structure is essential for
successful and meaningful investigations. For many other TMS applications the
                                        Transcranial Magnetic Stimulation     165

underlying brain topology is not necessarily required: For research applications
and investigations, a hot spot search is performed finding an optimal stimu-
lation point for each single subject by measuring the motor evoked potentials
(MEPs) of a specific muscle. Underlying brain structure is not needed for this
purpose [5]. Instead, it is more important to stimulate precisely at the hot spot
and to reaccess the hot spot in different trials or days.
    As MRI-scanner time is often hard to access and expensive, we propose usage
of 3D laser scanner to obtain a precise three dimensional contour of the subject’s
head that can be used for navigated and robotized TMS. Compared to MRI
scanner, laser scanner are easy to use and affordable. These systems are well
established in medical applications. Previous investigations have shown that 3D
laser scanner are suitable for 3D recordings of the human face [6]. Thus, 3D
laser systems could be used to generate a complete 3D surface of the head. We
evaluate the generated contour by laser scans by comparison with an MRI-scan
and with manual head contour generation. Additionally, we present exemplarily
the application in ongoing TMS investigations with the robotized system.


2     Materials and Methods

2.1   Hardware Setup
We use a GALAXY laser system (LAP GmbH Laser Applikationen, Lüneb-
urg, Germany) for head scanning and a human head phantom for testing. The
GALAXY laser scanner has a scan volume of 670 − 800 × 950 − 1300 × 490 −
600mm3 . The scanning time depends on the resolution and on the size of scan-
ning volume. The time needed to perform one scan is in the range of 1 − 5 s.
With a reduced resolution and in real time mode, the laser system can reach a
scanning frequency up to 5 Hz. The scanner has a repeatability of < 0.1 mm
and an accuracy in the acquired patient position of < 1 mm. The resolution in
the measurement axis of the laser scanner is specified with 0.2 mm for the y-
and z-axis, and 0.5 mm for the x-axis [7].


2.2   Head Scanning & Contour Generation
A high resolution laser scan of a human head consists of ≈ 9000 surface points.
The resulting laser image is shown in Figure 1(a). In Figure 1(b) the single data
points are visualized. A smooth head contour of single data points representing
the head is generated with the PowerCrust algorithm [8]. Figure 1(d) shows the
generated contour of the head phantom. In Figure 1(c) the contour is illustrated
with the underlying data points. Hair is a critical issue as hair absorbs laser
light. Therefore, we use white swimming caps that are tight-fitting to the head.
Note that this cap is only needed for laser scan acquisition. In contrast, MRI
head contour is generated using edge detection extracting the head surface in
the MRI images.
166     Richter et al.

3     Results
3.1   Comparison to MRI Scans
We used a head phantom to compare head contour generated by 3D laser scans
with head contour generated from MRI-scan. Therefore, we estimated the dis-
tance from every data point of laser scan to MRI head contour. Ten differ-
ent head phantom positions and scans were used. The mean error found was
0.289 mm with an RMS error of 0.358 mm and a maximum error of 0.984 mm.
Roughly, 10 − 15 % of data points had to be excluded due to noise and deflec-
tions, having still 6000 − 8000 data points for matching. Figure 2a illustrates a
laser scan overlaying the MRI head contour.




             (a)                   (b)               (c)               (d)

Fig. 1. Head phantom scanned by laser scanner. (a) Resulting scan in the scanning
software. (b) Each scan consists of ≈ 9000 single data points. (c) From the single data
points a head contour is computed. (d) Head contour computed with the PowerCrust
method [8].




                          (a)                         (b)

Fig. 2. MRI head contour of head phantom with overlying 3D laser scan. (a) larger
dark dots mark initial landmarks for registration; (b) manually generated.
                                        Transcranial Magnetic Stimulation     167

3.2   Comparison to Manual Contour Generation
A Pointer tracked by a Polaris Spectra stereo optic infrared tracking camera
(Northern Digital Inc., Waterloo, Ontario, Canada) can be used to generate
a manual head contour. For this purpose, the pointer is continuously tracked
while moved on the head surface. Typically, with this method 500 − 1000 surface
points are collected. Using again the PowerCrust algorithm [8] a head contour
can be generated. Figure 2b visualizes the inexactness of manual head generation
compared to 3D laser scans.


3.3   Usage in TMS Studies

Currently, we are successfully using head contours based on 3D laser scans for
two ongoing TMS studies with 20 subjects, so far.For both the studies, motor
cortex mapping has to be performed. A stimulation hot spot for right foot and
for left hand are identified for the first and second experiment, respectively. Once
the hot spot is found, the coil will be positioned exactly at the hot spot again
for stimulation. Figure 3 shows motor cortex mapping results for two subjects.
    During these TMS-experiments, we found that the overall error of the robo-
tized system using laser scans is < 5 mm. This was measured as the maximum
distance between coil and head. Note that robot-tracking calibration, coil and
head registration, and hair influence the accuracy besides the laser scan.


4     Discussion

We have shown that 3D laser scans of the head can be used as a navigation
source for TMS when no medical image data is on hand. Instead of a manual
head contour generation, where the data is collected with a pointer, it is more




            Fig. 3. Motor cortex mapping results based on laser scans.
168     Richter et al.

precise and appropriate to the head due to the fact that the laser scan consists
of a magnitude more points compared to a manual head contour.
    Our ongoing clinical trials have practically proven that 3D laser scans are
sufficient for application in navigated and robotized TMS systems. For a later
evaluation, registration of laser scans with acquired measurements to medical
images is possible.
    When data acquisition of 3D laser scans becomes real-time capable with
new technologies, it will be possible to use laser scans as navigation source and
for direct head tracking during stimulation [9]. This would speed up the whole
process and increase the acceptance of the system in clinical workflow as subjects
could be stimulated without any data preparation or registration.

Acknowledgement. The authors would like to thank LAP GmbH Laser Ap-
plikationen for providing the 3D laser system and equipment. This work was
partially supported by the Graduate School for Computing in Medicine and Life
Sciences funded by Germany’s Excellence Initiative [DFG GSC 235/1].


References
1. Pascual-Leone A, Davey NJ, Rothwell J, et al. Handbook of Transcranial Magnetic
   Stimulation. Arnold; 2002.
2. Ruohonen J, Karhu J. Navigated transcranial magnetic stimulation. Clin Neuro-
   physiol. 2010;40(1):7–17.
3. Langguth B, Kleinjung T, Landgrebe M, et al. rTMS for the treatment of tinnitus:
   the role of neuronavigation for coil positioning. Clin Neurophysiol. 2010;40(1):45–58.
4. Matthäus L, Trillenberg P, Bodensteiner C, et al. Robotized TMS for motion com-
   pensated navigated brain stimulation. In: Proc CARS; 2006. p. 373–8.
5. Balslev D, Braet W, McAllister C, et al. Inter-individual variability in optimal cur-
   rent direction for transcranial magnetic stimulation of the motor cortex. J Neurosci
   Methods. 2007;162(1-2):309 – 13.
6. Kovacs L, Zimmermann A, Brockmann G, et al. Three-dimensional recording of the
   human face with a 3D laser scanner. J Plast Reconstr Aesthet Surg. 2006;59(11):1193
   – 202.
7. LAP-Laser. GALAXY: Patient Topography Laser System. Tech Rep. 2009; p.
   245–61.
8. Amenta N, Choi S, Kolluri R. The power crust, unions of balls, and the medial axis
   transform. Comput Geometry: Theory Appl. 2001;19:127–53.
9. Richter L, Bruder R, Schlaefer A, et al. Towards direct head navigation for robot-
   guided transcranial magnetic stimulation using 3D laserscans: idea, Setup and fea-
   sibility. Proc IEEE EMBS. 2010; p. 2283–6.