Vim stimulation as a predictor of response to
deep brain stimulation in patients of severe
tremor undergoing dual stimulation

Krishe Menezes a1, Milind Deogaonkar b, and Vatsal Bajpai a

aUniversity of Toledo Health Science Campus, Toledo, OH 43614, and bWexner medical center, The Ohio State University, Columbus, OH, 43210

Background: Deep brain stimulation, targeting the ventral inter-
mediate nucleus of the thalamus (Vim), has been shown to be an
effective management tool for tremors refractory to other thera-
pies. There is some variance in response to Vim stimulation for
severe essential and rubral tremors.
Methods: This study looked at dual stimulations (addition, in
which the Vim is stimulated along with an additional nucleus or
augmentation, in which a second lead is placed within the Vim it-
self) for these types of tremors. A total of eight patients, four with
rubral and four with severe essential tremors, were treated with
deep brain stimulation. The responses of the patients were char-
acterized on a scale from excellent improvement to worsening of
condition.
Results: Two of the four patients with rubral tremor had an ex-
cellent response to Vim stimulation. These patients showed addi-
tional benefits when the prelemniscal radiation (Raprl) was stimu-
lated, in addition to the Vim. Three of the four patients with severe
essential tremor reported either a good or excellent response to
Vim stimulation. One of these patients had the Raprl stimulated in
addition to the Vim while another had an augmentation of the Vim,
with ventralis oralis posterior (Vop) stimulation. Both showed ad-
ditional benefits with the addition or augmentation performed.
Conclusions: We conclude that if a patient with severe medically
refractory tremor (essential or rubral tremor) responds to Vim
stimulation but is still disabled he will likely also have a response
to dual stimulation with an additional lead in the Raprl or an aug-
mentation with an additional lead in the Vop. Patients who did
not initially respond to Vim stimulation did not respond to the
placement of a second lead. We also conclude that for severe es-
sential tremor, Raprl stimulation showed a better response than
Vim stimulation.

tremor | Vim | Voa | Vop | Raprl | newer targets | multiple targets

Patients with tremor refractory to medical management are oftensent for ventral intermediate nucleus (Vim) of the thalamus deep
brain stimulation (DBS) surgery. Results are usually good. However,
in cases of severe essential tremor and rubral tremor the outcomes
of surgery are less predictable (1). Dual stimulations can be per-
formed in these cases for additional benefit. They can be performed
in two forms as follows: addition, in which the Vim is stimulated
along with an additional nucleus or augmentation, in which a sec-
ond lead is placed within the Vim itself (1-3). There is no existing
paradigm to predict how a patient will respond to the second stim-
ulation. This paper studies the responses of severe tremor to dual
stimulations (additions and augmentations) and sets a paradigm that
will help predict whether a second stimulation should be performed.
In addition this paper compares the effects of prelemniscal radiation
(Raprl) stimulation to the older and more traditional Vim target in
treating tremor.

Previous work (3-7) has shown promise in targeting areas other
than the Vim for essential and Holmes? tremor (rubral tremor), these

include the ventralis oralis anterior (Voa) and posterior (Vop) areas
of the thalamus and the globus pallidus internalis. Furthermore, it
has been suggested (5) that since a Holmes? tremor involves both
the cerebellothalamic and pallidothalamic circuits, combined stimu-
lation of the subthalamic and thalamic nuclei should lead to better
outcomes than Vim alone. The posterior subthalamic area, including
Raprl, have shown promise as a target for amelioration of both types
of tremors.

Materials and Methods
Case Selection. The study was carried out at the Center for Neuro-
logical Restoration at the Cleveland Clinic (Cleveland, Ohio). After
IRB submission and approval all patients with severe rubral tremor
and essential tremor undergoing stimulation of either a new target or
multiple targets were selected. A new target was defined as any target
other than Vim. These included Voa, Vop and Raprl. Multiple targets
was defined as any combination of more than one target.

Case Evaluation. Response to stimulation of each target was char-
acterized as: Excellent improvement (50% or greater improvement
from previous functioning as judged by the patient), Good (25-49%
improvement), Mild (less than 25% improvement), unchanged and
worse. Response to stimulation of new targets as well as dual target
stimulations was assessed similarly. The Fahn-Tolosa-Marin Tremor
Rating Scale was not used as this was a retrospective study based on
a chart review. This is also the reason why these patients were not
followed prospectively.

Statistical Analysis. The number of cases in the series was small
(eight) therefore each case was looked at individually under the broad
categories of change in function that is: a) Excellent improvement,
b) Good improvement, c) Mild improvement, d) Unchanged and e)
Worse.

Results
A total of eight patients were treated with deep brain stimulation

for either rubral or essential tremor. There were four cases of rubral
tremor and four of severe essential tremor. Relevant clinical data are
1To whom correspondence should be sent: Krishe.Menezes@utoledo.edu

Author contributions: KM is responsible for conception, organization, and execution of the re-
search project, design, execution and review of the analysis, and for writing and reviewing the
manuscript. MD supervised data analysis, contributed to conception and organization of the
research project, and review of the manuscript. VB contributed to drafting of the manuscript
and literature review. KM takes responsibility for the paper as a whole.

The authors declare no conflict of interest

Freely available online through the UTJMS open access option

utdr.utoledo.edu/translation/ UTJMS 2015 Vol. 2 7–10



Table 1: Clinical profile of individual patients

Pt # Age Gender Tremor Type

1 34 M rubral
2 51 M rubral
3 55 M rubral
4 58 M rubral
5 74 M essential
6 75 M essential
7 79 F essential
8 81 F essential

presented in Table 1.Four of the eight cases were resolved satisfac-
torily after Vim stimulation. The rest required further stimulations
involving Raprl, Vim/ Vop and Vop as tremor control was inadequate
with Vim stimulation alone. Details of these stimulations in terms of
site of stimulation and the order in which they were performed are
shown in Table 2.

Table 2: Total number of surgical procedures performed on each
patient

Pt # Number of Type of procedurea

procedures

1 1 Right-Vim

2 1 Left Vim + Left Raprl

3 1 Right Vim + Right Raprl

4 2 Right Vim, Vim lead reimplanted (for
lead break),
Right Raprl added to Vim

5 3 Left Vim, Right Vim, Left Vim + Left
Vim/ Vop

6 3 Left Vim, Left Raprl, Left Raprl lead
replacement for lead break

7 1 Left Vim + Left Vop

8 5 Left Vim, Re-implanatation of Left
Vim, Right Vim attempted,
Right Raprl, Left Raprl (Left Vim left
in place)

a Vim- Ventral intermediate nucleus of the thalamus; Rapl-
prelemniscal radiation; Vop- ventralis oralis posterior nu-
cleus of the thalamus

Rubral tremor outcomes. The four patients with rubral tremor re-
sponded differently to Vim stimulation. Two of the four (50%) had an
excellent response, while the other two (50%) had a mild response.
Three patients had additional stimulation (Vim + Raprl). Of these,
Patient 2, who had a mild response to Vim stimulation, also showed a
mild response to addition of Raprl stimulation. The two patients who
showed an excellent response to Vim stimulation had an even better
response (further reduction in tremor and improvement in function)
with additional Raprl stimulation as compared to Vim stimulation
alone. This data is summarized in Table 3.

Essential tremor outcomes. There were four patients with advanced
essential tremor, and three of them (Patients 5, 6 and 8) had a good
or excellent response with Vim stimulation. Of these three patients,
patient 5 had an augmentation of Vim stimulation with Vop stimu-
lation. This led to a better response than that achieved only through
Vim stimulation alone. Patients 6 and 8 had Vim stimulation in ad-
dition to Raprl stimulation which led to an excellent response. In pa-

tient 8, the addition of Raprl stimulation showed additional benefits
as compared to Vim stimulation alone. Patient 7 had an augmentation
of Vim with Vop. The response of the augmentation was mild as was
seen with stimulation of Vim alone. The patient responses are shown
in Table 4.

Table 3: Rubral tremor outcomes

Pt # First surgical sessiona Second surgical session

1 - Right Vim
mild response

-

2 Left Vim-
mild response

Left Raprl
(addition)- mild
response

-

3 Right Vim -
excellent
response

Right Raprl
(addition)-
excellent
response with
additional benefits

-

4 Right Vim -
excellent
response

- Right Raprl
(addition)-
excellent
response with
additional benefits

a Column hyphens indicate absence of another stimulation at that
surgical session

Table 4: Advanced essential tremor outcomes

Pt # First surgical Second surgical Third surgical
sessiona session session

5 Left Vim
excellent
response

- Right
Vim
good
response

- Left Vim/Vop
(augmentation)
excellent response
with additional
benefits

6 Left Vim
mild
response

- Left Raprl
(addition)
excellent
response

- -

7 Left Vim
excellent
response

Left Vop
(augmentation)
mild response

- - -

8 Left Vim
excellent
response

- Right
Raprl
excellent
response

- Left Raprl
(addition)
excellent response

a Column hyphens indicate absence of another stimulation at that sur-
gical session

Side effects. A total of 9 side effects resulted from the therapeutic
interventions. These side effects are enumerated in Table 5. Of the
twelve patients that had the Vim stimulated nine (75%) experienced
side effects. These included dysarthria, electric sensation, limb weak-
ness, throat constriction and hemorrhage. There was additional left-
handed numbness (with Raprl stimulation) and post-operational con-
fusion (with Vop stimulation) when augmented stimulation was used
along with Vim. Of the four procedures where only the Raprl was
stimulated three (75%) did not lead to any complications. One of
the patients experienced seizures. The most common complication
overall was dysarthria, followed by limb weakness and an electric
sensation in the limbs.

8 utdr.utoledo.edu/translation/ Menezes et al.



Table 5: Complications from stimulation of various areas

Complications Total
Area No. side Dys- Left hand Electric Limb Throat Post-op Postural Seiz- Hemor- Proced-

Stimulated effects arthria numbness sensation weakness constriction confusion instability uses rage ures

Vim 3 3 2 2 1 1 2

Vim + Raprl 1 1 1 3

Vim + Vop 1 1 1 3

Raprl 3 1 4

Total
complications

7(no comp-
lications 5)

5 1 2 2 1 1 1 1 1

Discussion
Additions and Augmentations. DBS of the Vim is very effective in
managing medication refractory essential tremor (8-11). With medi-
cations tremor control is at best 50% (12) but with Vim DBS tremor-
control is achieved in around 80% of patients (13,14). In some pa-
tients with severe tremor however the effect of Vim stimulation is
less predictable. These are patients with rubral tremor and severe
essential tremor (15). In these patients additions and augmentations
of stimulation have been performed with additional benefit in some
(5,6). Additions consist of stimulation of an additional nucleus e.g.
If a patient has had Vim stimulation then an addition would consist
of Vim + Raprl stimulation (See Fig. 1 below). In some patients
augmentation was performed, e.g. Vim + Vop (See Fig. 1 below).
The issue so far has been the absence of an available algorithm to
predict whether performing an addition or augmentation will provide
additional benefit to the initial Vim stimulation. In our series of pa-
tients we found that, in both rubral tremor as well as severe essential
tremor, if Vim stimulation produced a good response then an addition
or an augmentation produced additional benefit. However, if there
was an absence of a good response to Vim, additions and augmenta-
tions did not show additional benefit. Additions and augmentations
act by increasing the inhibition of thalamic output to the cortex (4,
5, 15). It is unclear how this may be taking place but in all proba-
bility it is due to an additive frequency being provided by the second
stimulator through the second lead (4, 5, 16). This frequency can
be delivered to another spot in the same nucleus (augmentation) or to
another spot in the tract like the Raprl (addition) which inputs into the
Vim. The electrical effect is of providing double the frequency (two
stimulators providing around 130Hz each) as compared to a single
stimulation (1-3, 5-7). For some reason most patients cannot tolerate
turning up the frequency very high through a single lead but can do so
if fractionated over 2 spots in the same nucleus or one in the nucleus
and another in an afferent tract (Raprl) (17). Doubling the frequency
provides increased inhibition and therefore a better therapeutic effect
(4,6). With the new stimulators it is possible to produce this effect
by interleaving, that is running two programs on the same lead in the
Vim so that the overlapping area gets double the frequency. The basic
question still remains as to why some of these tremors show a good
response to the initial Vim stimulation and others do not. It appears
that the physiology of tremor in the non-responders is different (4-7).
These patients may have the tremor generating oscillator outside the
stimulated circuit which has traditionally been thought of as being the
cerebello-thalamic and pallido-thalamic pathways (5,15). It has been
shown that the Raprl has fibers that originate from the mesencephalic
reticular formation, connecting it to the thalamus via the ascending
cerebellothalamic fibers (17-23). These fibers project onto the ven-
trolateral thalamus, including the Vim. Stimulation of the Raprl is a

good point to catch these ascending cerebellothalamic fibres as they
converge together here before entering the thalamus. The Vop, the
pallidal afferent pathway, have been shown to be an effective target

Fig. 1: Sagittal section through the thalamus. Schematic diagram
showing the position of the DBS electrode in relation to the
path of the cerebello?Vim fibers from the dentate and inter-
positus nuclei on the left side. The electrode is placed where
these fibers are concentrated together in the subthalamic re-
gion before ?fanning out? to the large body of the Vim above.
Cd = caudate nucleus; GPi = globus pallidus internus; IC =
internal capsule; PUT = putamen.

Menezes et al. UTJMS 2015 Vol. 2 9



area for amelioration of essential tremor (4). While the exact patho-
logical loop that connects the Vim and Vop is not known, it has been
shown that the Vop might have a greater effect on tremor control
than previously imagined. The Vop has been hypothesized to be a
cerebellar receiving area (24) and some cells of this area have been
implicated in tremor related activity (25). This would explain the
additional benefits from Vop stimulation in addition to Vim.

Raprl stimulation alone had a better outcome than Vim stimula-
tion alone in advanced essential tremor. Raprl stimulation alone for
advanced essential tremor had a better success rate than Vim alone.
The explanation for this is two-fold. Firstly, it has been shown that
more energy is required for exciting cell bodies than for myelinated
fiber tracts (17). Secondly, the fibers from the interposed nucleus
of the cerebellum are more abundant and more compactly packed in
the posterior subthalamic area than in the thalamus (18). For these
reasons a single electrode stimulation of the Raprl leads to a better
response than stimulation of the Vim. A larger number of cases will
have to be systematically studied to validate this conclusion.

Loss of benefit over time in advanced essential tremor. In all the
above patients the effect of DBS in essential tremor wore off with
time due to tolerance. In some of these patients the benefit can be
regained by reprogramming (11-14). However an initial poor re-

sponse to DBS could not be fixed by conventional reprogramming
and therefore dual stimulations were used. This suggests that those
tremors that are responsive to DBS have a different electrical phys-
iology from those that are not responsive. DBS can overwrite the
abnormal discharge in the responsive patients. In these patients if the
abnormal signal re- emerges it can again be taken down by a new
DBS program. However patients who are unresponsive seem to have
a different electrical signal that cannot be overwritten by DBS.

Resistance to DBS. Most tremors are generated by central oscilla-
tors. In essential tremor it is most likely the inferior olive (26). In
rubral tremor it is thought to be the thalamus (27). One question
remains: In patients who do not respond to DBS could the oscilla-
tors be located outside the cerebellothalamicocortical pathway? This
is unlikely as it has repeatedly been shown (28, 29) that the central
oscillatory circuit in essential tremor is the olivo?cerebello?thalamic
circuit. The failure to respond to DBS is possibly due to a different
form of electrical signal or a different signal to noise ratio in these
patients which seems to bypass the suppressive effect created by elec-
trical noise from the DBS. This hypothesis will have to be proven by
further studies.

ACKNOWLEDGMENTS. Dr. Milind Deogaonkar consults for Medtronic.

1. Lim DA, et al. (2007) Multiple target deep brain stimulation for Multiple Sclerosis
related and poststroke Holmes tremor. Streotact Funct Neurosurg 85:144-149.

2. Yamamoto T, et al. (2001) New method of deep brain stimulaion therapy with two
electrodes implanted in parallel and side by side. J Neurosurg 95:107-1078.

3. Foote KD, et al. (2006) Dual electrode thalamic deep brain stimulation for the treat-
ment of posttraumatic and multiple sclerosis tremor. Neurosurgery 58(4):ONS-280-
ONS-286.

4. Yamamoto T, et al. (2004) Deep brain stimulation for the treatment of parkinsonian,
essential and poststroke tremor: a suitable stimulation method and changes in
effective stimulation intensity. J Neurosurg 101:201-209.

5. Romanelli P, Brönte-Stewart H, Courtney T, Heit G (2003) Possible necessity for
deep brain stimulation of both the ventralis intermedius and subthalamic nuclei to
resolve Holmes tremor. J Neurosurg 99:566-571.

6. Foote KD, Okun MS (2005) Ventralis intermedius plus ventralis oralis anterior and
posterior deep brain stimulation for posttraumatic Holmes tremor: two leads may
be better than one: technical note. Neurosug 56(4):E445.

7. Gato S, Yamada K (2004) Combination of thalamic Vim stimulation and GPi palli-
dotomy synergistically abolishes Holmes? tremor. J NEurol Neurosurg Psychiatry
75:1203-1204.

8. Benabid AL, et al. (1991) Long-term suppression of tremor by chronic stimulation
of ventral intermediate thalamic nucleus. Lancet 337:403-406.

9. Benabid AL, et al. (1996) Chronic electrical stimulation of the ventralis intermedius
nucleus of the thalamus as a treatment of movement disorders. J Neurosurg 84:203-
214.

10. Benabid AL, et al. (1998) Long-term electrical inhibition of deep brain targets in
movement disorders. Mov Disord 18:1000-1007.

11. Pahwa R, et al. (2006) Long-term evaluation of deep brain stimulation of the thala-
mus. J Neurosurg 104:506-512.

12. Lyons KE, et al. (2003) Benefits and risks of pharmacological treatments for essen-
tial tremor. Drug Saf 26:461-481.

13. Koller WC, Lyons KE, Wilkinson SB, Troster AI, Pahwa R (2001) Long-term safety
and efficacy of unilateral deep brain stimulation of the thalamus in essential tremor.
Mov Disord 16:464-68.

14. Rehncrona S, et al. (2003) Long-term efficacy of thalamic deep brain stimulation for
tremor: double-blind assessments. Mov Disord 18:163-70.

15. Perlmutter JS, Mink JW (2006) Deep Brain Stimulation. Annu Rev Neurosci 29:229-
257.

16. Lim DA, et al. (2007) Multiple target deep brain stimulation for multiple sclerosis
related and poststroke Holmes’ tremor. Stereotact Funct Neurosurg 85:144-149.

17. Hamel W, et al. (2007) Deep brain stimulation in the subthalamic area is more ef-
fective than nucleus ventralis intermedius stimulation for bilateral intention tremor.
Acta Neurochir (Wien) 149:749-758.

18. Murata J, et al. (2003) Electrical stimulation of posterior subthalamic area for the
treatment of intractable proximal tremor. J Neurosurg 99:708-715.

19. Velasco F, et al. (2001) Electrical stimulation of the Prelemniscal Radiation in the
treatment of Parkinson?s disease: An old target revised with new techniques. Neu-
rosurgery 49 (2):293-306.

20. Raethjen J, et al. (2000) Multiple Oscillators are causing Parkinsonian and Essential
Tremor. Mov Disorders 15:84-94.

21. Herzog J, et al. (2007) Kinematic analysis of thalamic versus subthalamic neu-
rostimulation in postural and intention tremor. Brain 130:1608-1625.

22. Blomstedt P, Sandvik U, Fytagoridis A, Tisch S (2009) The posterior subthalamic
area in the treatment of movement disorders: past, present and future. Neuro-
surgery 64:1029-1042.

23. Carrillo-Ruiz JD, et al. (2008) Bilateral electrical stimulation of prelemniscal radia-
tions in the treatment of advanced Parkinson?s disease. Neurosurgery 62:347-359.

24. Krack P, et al. (2002) Surgery of the Motor Thalamus: Problems with the present
nomenclatures. Mov Disord 17(S3):S2-S8.

25. Lenz FA, et al. (1994) Single unit analysis of the human ventral thalamic nuclear
group. Tremor-related activity in functionally identified cells. Brain 17 (3):531-543.

26. Hua SE, Lenz FA (2005)Posture-related oscillation in Human Cerebellar Thalamus
in Essential Tremor are enabled by voluntary motor circuits. J Neurophysiol 93:117-
127.

27. Kassubek J, Landwehrmeyer GB, Lücking CH, Juengling FD (2003) Post ischemic
Holmes tremor investigated by FDG and H2 15O-PET. J Radiology 6:1-8.

28. Elble RJ. (1996) Central mechanisms of tremor. J Clin Neurophsiol 13:133-144.
29. Deuschl G, Wenzelburger R, Raethjen J (2000) Tremor. Curr Opin Neurol 13:437-443.

10 utdr.utoledo.edu/translation/ Menezes et al.