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TRH analogue affects information transfer through the ventrobasal thalamus
Neuropeptides
7: 31-39, 1986
TRH ANALOGUE AFFECTS INFORMATION TRANSFER THROUGH THE VENTROBASAL THALAMUS Kenneth A. Clarke Department
of Physiology,
University of Sheffield, Western Bank,
Sheffield SlO 2TN, England. ABSTRACT Extracellular ventrobasal
microelectrode
recordings have been made from single
thalamic neurones in rats anaesthetised
Injection of the thyrotropin releasing hormone (Zmg/kg), produced increases in spontaneous the latency of response to peripheral increased production
with urethane.
(TRH) analogue RX77368
activity and decreases in
stimulation,
of later, rhythmic discharges.
together with These changes
were maximal between 30 and 60 minutes after injection.
Decreases in
latency and increases in amplitude were also observed in the evoked potential
recorded from the somatosensory
discussed in relation to previously
cortex.
These results are
observed effects of TRH.
Since
this system is important in the planning and execution of motor acts it is suggested that modification
of information
system could have effects on the production
flow through this
of motor activity.
INTRODUCTION A number of studies have indicated that administration analogues produce increases in motor activity
of TRH or its
(1,2,3,4,5).
Areas of
the CNS associated with motor control have been identified which are either directly sensitive to TRH application excitable
after systemic administration
(6,7,8), or become more
(9,lO).
However, motor
activity is determined not only by alterations on the motor output side, but also by alterations myoclonus,
in sensory input.
For example, in post-anoxic
a condition in which there is thought to be a functionally
deficient descending
5HT pathway, the elevated muscular
responses to
sensory stimulation may arise as a result of changes on the sensory
31
side and the reflex connections between the sensory input and motor output, rather than by any increases in motor excitability
(11).
dorsal column, medial lemniscal system is thought to provide constantly updated, tactile sensory input
The
a
(12) which is important in
the initiation and direction of exploratory motor activity. Extracellular
single unit recordings have been made from the ventro-
basal thalamus in urethane anaesthetised TRH analogue
(RX77368) produces
in information
rats to determine whether a
changes in activity of, or alterations
flow through, this system, since this could have
profound consequences
for the programming
of the motor output.
METHODS l.. Anaesthesia Experiments
and preparation
have been performed
on 12 female rats
within the weight range 190-21Og.
Anaesthesia
of an i.p. injection of ethyl carbamate
was induced by means
(25% in 0.9% saline) and the
dose adjusted to abolish hindlimb withdrawal 1.3 - 1.5 g/kg).
(Sheffield strain)
A tail vein was cannulated
to a strong pinch
(range
followedbyexcision
of
the dura mater over Cl in order to release CSF pressure and prevent cerebral oedema.
A left-sided craniotomy was then performed
animal mounted in a stereotaxic
frame (14).
and the
A paraffin pool was
constructed over the exposed cortex by clamping the cut skin edges. A rectal thermometer was used to monitor body temperature which was maintained by means of a radiator beneath the animal and a heating lamp above it.
2. Recording and analysis The right forepaw was electrically
stimulated
(square wave pulses,
40-7OV, O.lmsec duration, rate 0.25H.z, negative electrode on wrist positive on digit 2) and recordings made from single ventrobasal thalamic units located and identified as in Angel and Clarke Evoked cortical potentials the primary somatosensory
were recorded from the geometric cortex
(14).
(13). centre of
Cortical recording was by
means of silver ball electrodes with the reference electrode being on Thalamic units were recorded through glass
the occipital
cortex.
micropipettes
filled with 3M saline, tip diameters 2-5!Jm. The signals
32
were passed through an FET, filtered, amplified and displayed on a Tektronix
RS103N oscilloscope
for each of the units.
calculated using Wilcoxons
recorded on magnetic
Latencies anddischarge
tape for further analysis. calculated
and simultaneously
Significance
Signed Ranks Test.
frequencies
were
of any changes was Cortical evoked
potentials
were filtered, amplified and averaged using a Neurolog NL750
Averager,
the Averager output processed
through a BBC microcomputer
and displayed using an Epson MX80111 printer. histograms
for ventrobasal
Post-stimulus
thalamic units were prepared in a similar
fashion. 3. TRH analogue Thyrotropin
releasing hormone analogue
(p Glu-His(3,3'-dimethyl-ProNH2)
(RX77368) generously donated by Reckitt & Colman was given intravenously
(Hull, Yorkshire),
via a tail vein cannula, as a dose of 2mq/kg
dissolved in 0.9% saline at a concentration
of 2mg/ml.
Injection
delivery time was 30 to 60 seconds. RESULTS 1. Spontaneous Spontaneous
activity
activity was measured
RX77368 injection was 1.25+0.95
in 20 VBT neurones.
(mean + 1 SEM).
Activity before
Increases in
24’
‘;; aJ ul . ._
e_;
11111,~ I(/ 0
II
I
I
I
Time(min)
Figure 1. Interval histogram
60
of spontaneous discharge of a VBT neurone.
Each line is the mean discharge frequency one minute period.
Ill,
(imp/set), averaged over a
Injection of RX77368 at T=l minute.
33
spontaneous activity were observed in 17 of the 20 neurones
(Fig. I)..
Changes often occurred within 1 minute of injection, however, maximum increases were seen between 12.5+3.7
33 and 57 minutes after injection to
(mean + 1 SEM, n = 20) imp/set.
(~~0.05).
2. Short latency evoked responses The effects of RX77368 injection on the short latency responses of 8 VBT neurones to peripheral
stimulation was determined.
A reduction in
the latency of response was observed in 6 of the neurones 5.27kO.48 msec before injection to 4.80+0.43
from
(mean + 1 SEM, n = 8,
p
msec after injection.
histogram
is shown for one of the units in Fig. 2.
A post-stimulus
latency Two neurones were
unaffected.
3
b. .I
0
6
Tlmetmsec)
Figure 2. Post-stimulus
histograms
of a VBT neurone, before RX773bS.
0
10
6
of short-latency
(left) and after
I
Tlmefmsec)
10
evoked discharges
(right) injection of
Each plot built from responses to 128 consecutive
stimuli.
3. Long latency responses The effects of RX77368 injection on long latency evoked responses were observed in 8 VBT neurones.
In 5 of the 8 units there were no
long latency responses present prior to injection.
In the remaining
three, discharges were produced between 75 and 250 msec after stimulation. particular producing
However, there was no evidence to suggest that any
latency within this range was particularly discharges.
favourable
After RX77368 injection, however,
34
for
5 of the 8
units developed rhythmically
Figure 3. Post-stimulus of a VBT neurone, before
repeated discharges
(Fig. 3).
histograms of long latency evoked discharges (left) and after
(right), injection of
Each plot is built from the responses to 128 consecutive
RX77368. stimuli.
Four of the five units produced a burst of discharges within the range 88.8 to 98.1
(mean = 94.0) msec after stimulation,
a burst of discharges
in the range 133.2 to 144.8 (mean = 140.2) msec
and four of the five a burst of discharges 205.6
three of the five
(mean = 198.0) msec.
in the range 184.6 to
In the remaining three units, rhythmicity
did not develop. 4. Somatosensory Measurements
cortical evoked responses
of the somatosensory
experiments.
Reductions
evoked potential were made in five
in the latencies and increases in the
amplitudes of both the Pl and Nl waves were observed
(Table 1 and
Fig. 4). Pl Before After
RX RX
Latency
6.2 (0.2) 5.7 (0.17)*
Nl
Latency
Pl
Amplitude
1.6 (0.2)
100
7.2 (0.14)
(35.4)
178
Table 1. Latency to peaks of Pl and Nl waves. + 1 SEM, n = 5.
Amplitude 100
223
(41.9)X
Each figure is the mean
Also shown are the peak amplitudes of these waves,
expressed as a % of control value. control values
Nl
(~~0.05)
Significant
shown by *.
35
differences
from
r-----l. -\ i---> / \ ‘1_ ,-$-$ r-.?,? i, /
I
0
Tlmetmsec)
Figure 4. Post-stimulus (upper) and after
2k before
averaged cortical evoked potential,
Each average is
(lower), injection of RX77368.
built from the responses to 128 consecutive
stimuli.
Vertical
calibration bar is 100 UV. DISCUSSION It has been demonstrated
in these experiments
that systemic injection
of RX77368 produces an increase in excitability
of neurones in the
VBT as measured by their decrease in latency to a peripheral stimulus.
It is not possible
from ,the present experiments
to
determine whether or not this is as a result of direct effects on the VBT.
Ionophoretic
both excitatory
studies on neurones
in thalamic nuclei have shown
(15) and inhibitory effects
size or synchrony of the cuneothalamic
(16).
An increase in the
volley would seem to be
unlikely since cuneate neurones are either unaffected ionophoresis
of TRB
or inhibited by
(17).
Increases in the incidence of later, rhythmic discharges were also observed after RX77368 injection taking the form of bursts of impulses occurring within particular post-stimulus 94,140 and 198ms.
latency windows at around
This effect on thalamic rhythmicity
in view of the observation
is interesting
(7) that neurones in the septum which are
rhythmically
active are more often excited by TRB than are non-
rhythmically
active neurones.
The observation
of increased spontaneous
activity of neurones in the
VBT indicates that the changes in excitability
36
are not just phasic
changes associated with the processing
of the input volley but due to
rather more tonic changes in excitability. Increases in both the Pl and Nl waves of the somatosensory potential were observed.
The increase in the Pl wave is compatible volley, though it is not possible
with an increased thalamocortical to determine
evoked
from the present experiments whether the elevated Nl
wave occurs as a result of the increased input or whether there are additional effects on the cerebral cortex or other cortical inputs. Iontophoretic
studies have produced
little agreement on the effects
of TRH on single neurones in the cerebral cortex. failed to demonstrate effects
a direct effect
(8,18,19),othersexcitatory
(6,15) and others inhibition
consistent observation
(16,171.
excitatory
formation modulate
(6,8,18,19).
Since powerful
of the VBT
(Zl), the possibility
of a cholinergic mechanism by RX77368 in the
of increased excitability
present experiments,
reticular
(20) and since neurones in the reticular
the excitability
exists for potentiation
produces
of cholinergic
cholinergic pathways exist between the brainstem
formation and the VBT
production
However, a more
has been the potentiation
excitation of cortical cells by TRH
Some studies have
of VBT cells.
Thus in the
it has been shown that the TRH analogue RX77368
increases in the excitability
of a sensory input system whicl-
is closely integrated with the motor output system. important consequences
This may have
on the ability to plan and execute motor
activity.
REFERENCES 1. Ervin, G., Schmitz, S.A., Nemeroff, C.B. et al (1981) Thyrotropin releasing hormone and amphetamine produce different patterns of behavioural
excitation
in rats.
European J. Pharmacol.,
72, 35-43
2. Metcalf, G., Dettmar, P-W., Fortune, D. et al (1982) Neuropharmacological thyrotropin
evaluation of RX77368 - a stabilised analogue of
releasing hormone
(TRH).
193-206
37
Regulatory Peptides,
3,
3. Webster, Y.A.D., Griffiths,
E.C. and Slater, P. (1982) Induction
of wet dog shaking in rats by analogues and metabolites thyrotrophin
releasing hormone
(TRH).
Regulatory
of
Peptides,
5,
43-51 4. Andrews, J.S. and Sahgal, A. (1983) Effects of a thyrotropin releasing hormone, metabolites
and analques
in rats.
7, 97-111
Regulatory
Peptides,
5. Clarke, K.A. and Parker, A.J.
on locomotor activity
(1985) Effects of a thyrotropin
releasing hormone analogue on locomotor and other motor activity in the rat.
Neuropeptides,
6, 101-112
6. Braitman, D.J., Auker, C.R.E. and Carpenter, releasing hormone has multiple
D.O.
actionsin cortex.
(1980) Thyrotropir Brain Research,
194, 244-248 7. Lamour, Y., Dutar, P. and Jobert, A.
(1985) Effects of TRH, cycle -
(His-Pro) and (3-Me-His2) TRH on identified septohippocampal neurons in the rat.
Brain Research,
8. Winokur, A. and Beckman, A.L.
of neurones in the hypothalamus,
9.
Brain Research,
2 343-347
(1978) Effects of thyrotropin
releasing hormone, norepinephrine
the rat.
331,
and acetylcholine
on the activity
septum and cerebral cortex of
150, 205-209
Cooper, B.R. and Boyer, C.E.
(1978) Stimulant action of thyrotropin
releasing hormone on cat spinal cord.
Neuropharmacology,
17,
153-156 10. Clarke, K.A. and Stirk, G.C. administration
(1983) Motoneurone
of a thyrotrophin
British J. Pharmacol.,
excitability
releasing hormone
after
analogue.
80, 561-565
11. Chadwick, D., Hallett, M., Harris, R. et al (1977) Clinical, biochemical
and physiological
features distinguishing
myoclonus
responsive to 5_hydroxytryptophan,
tryptophan with a monoamine
oxidase inhibitor and clonazepam.
Brain, 100, 455-487
38
12. Wall, P.D.
(1970) The sensory and motor role of impulses travelling
in the dorsal columns towards cerebral cortex. 13. Angel, A. and Clarke, K.A.
(1975) An analysis of the representation
of the forelimb in the ventrobasal rat.
J. Physiol.,
Brain 93, 505-524
thalamic complex of the albino
249, 399-423
14. Angel, A., Berridge, D.A. and Unwin, J. (19731 The effect of anaesthetic agents on primary cortical evoked responses. British J. Anaesthesia,
45, 824-836
15. Barbichev, V-N., Ignatkov, V. Ya, Svachkin, Yu, P. and Smirnova, A. (1981) Comparative
analysis of the sensitivity of single neurons
of the central nervous system to thyrotropin its structural analog.
Neuroscience
releasing hormone and
and Behavioural
Physiology,
11, 385-388. 16. Moss, R.L.
(1977) Role of hypophysiotrophic
mediating neural and behavioural
neurohormones
events. Federation
in
Proceedings,
36(2), 1978-1983 17. Renaud, L-P., Martin, J-B., Brazeau, P. (1975) Depressant of TRH, LH-RH and somatostatin
action
on activity of central neurones.
Nature, 255, 233-235 18. Stone, T. (1983) Actions of TRH and cycle-(His-Pro) and evoked activity of cortical neurones.
on spontaneous
European J. Pharmacol.,
92, 113-118 19. Yarbrough,
G. (1983) Thyrotropin
cholinergic neurons. 20. McCance,
releasing hormone and CNS
Life Sciences,
33,(l), 111-118.
I., Phillis, J.W., and Westerman,
choline sensitivity
synaptic transmission.
British J. Pharmac.,
21. Angel, A. (1977) Processing Neurobiology,
R.A.
(1968) Acetyl-
of thalamic neurones: its relationship 32, 635-651
of sensory information.
9, 1-122
Received 27/9/85 Accepted 15/10/8S
39
to
Progress in
7: 31-39, 1986
TRH ANALOGUE AFFECTS INFORMATION TRANSFER THROUGH THE VENTROBASAL THALAMUS Kenneth A. Clarke Department
of Physiology,
University of Sheffield, Western Bank,
Sheffield SlO 2TN, England. ABSTRACT Extracellular ventrobasal
microelectrode
recordings have been made from single
thalamic neurones in rats anaesthetised
Injection of the thyrotropin releasing hormone (Zmg/kg), produced increases in spontaneous the latency of response to peripheral increased production
with urethane.
(TRH) analogue RX77368
activity and decreases in
stimulation,
of later, rhythmic discharges.
together with These changes
were maximal between 30 and 60 minutes after injection.
Decreases in
latency and increases in amplitude were also observed in the evoked potential
recorded from the somatosensory
discussed in relation to previously
cortex.
These results are
observed effects of TRH.
Since
this system is important in the planning and execution of motor acts it is suggested that modification
of information
system could have effects on the production
flow through this
of motor activity.
INTRODUCTION A number of studies have indicated that administration analogues produce increases in motor activity
of TRH or its
(1,2,3,4,5).
Areas of
the CNS associated with motor control have been identified which are either directly sensitive to TRH application excitable
after systemic administration
(6,7,8), or become more
(9,lO).
However, motor
activity is determined not only by alterations on the motor output side, but also by alterations myoclonus,
in sensory input.
For example, in post-anoxic
a condition in which there is thought to be a functionally
deficient descending
5HT pathway, the elevated muscular
responses to
sensory stimulation may arise as a result of changes on the sensory
31
side and the reflex connections between the sensory input and motor output, rather than by any increases in motor excitability
(11).
dorsal column, medial lemniscal system is thought to provide constantly updated, tactile sensory input
The
a
(12) which is important in
the initiation and direction of exploratory motor activity. Extracellular
single unit recordings have been made from the ventro-
basal thalamus in urethane anaesthetised TRH analogue
(RX77368) produces
in information
rats to determine whether a
changes in activity of, or alterations
flow through, this system, since this could have
profound consequences
for the programming
of the motor output.
METHODS l.. Anaesthesia Experiments
and preparation
have been performed
on 12 female rats
within the weight range 190-21Og.
Anaesthesia
of an i.p. injection of ethyl carbamate
was induced by means
(25% in 0.9% saline) and the
dose adjusted to abolish hindlimb withdrawal 1.3 - 1.5 g/kg).
(Sheffield strain)
A tail vein was cannulated
to a strong pinch
(range
followedbyexcision
of
the dura mater over Cl in order to release CSF pressure and prevent cerebral oedema.
A left-sided craniotomy was then performed
animal mounted in a stereotaxic
frame (14).
and the
A paraffin pool was
constructed over the exposed cortex by clamping the cut skin edges. A rectal thermometer was used to monitor body temperature which was maintained by means of a radiator beneath the animal and a heating lamp above it.
2. Recording and analysis The right forepaw was electrically
stimulated
(square wave pulses,
40-7OV, O.lmsec duration, rate 0.25H.z, negative electrode on wrist positive on digit 2) and recordings made from single ventrobasal thalamic units located and identified as in Angel and Clarke Evoked cortical potentials the primary somatosensory
were recorded from the geometric cortex
(14).
(13). centre of
Cortical recording was by
means of silver ball electrodes with the reference electrode being on Thalamic units were recorded through glass
the occipital
cortex.
micropipettes
filled with 3M saline, tip diameters 2-5!Jm. The signals
32
were passed through an FET, filtered, amplified and displayed on a Tektronix
RS103N oscilloscope
for each of the units.
calculated using Wilcoxons
recorded on magnetic
Latencies anddischarge
tape for further analysis. calculated
and simultaneously
Significance
Signed Ranks Test.
frequencies
were
of any changes was Cortical evoked
potentials
were filtered, amplified and averaged using a Neurolog NL750
Averager,
the Averager output processed
through a BBC microcomputer
and displayed using an Epson MX80111 printer. histograms
for ventrobasal
Post-stimulus
thalamic units were prepared in a similar
fashion. 3. TRH analogue Thyrotropin
releasing hormone analogue
(p Glu-His(3,3'-dimethyl-ProNH2)
(RX77368) generously donated by Reckitt & Colman was given intravenously
(Hull, Yorkshire),
via a tail vein cannula, as a dose of 2mq/kg
dissolved in 0.9% saline at a concentration
of 2mg/ml.
Injection
delivery time was 30 to 60 seconds. RESULTS 1. Spontaneous Spontaneous
activity
activity was measured
RX77368 injection was 1.25+0.95
in 20 VBT neurones.
(mean + 1 SEM).
Activity before
Increases in
24’
‘;; aJ ul . ._
e_;
11111,~ I(/ 0
II
I
I
I
Time(min)
Figure 1. Interval histogram
60
of spontaneous discharge of a VBT neurone.
Each line is the mean discharge frequency one minute period.
Ill,
(imp/set), averaged over a
Injection of RX77368 at T=l minute.
33
spontaneous activity were observed in 17 of the 20 neurones
(Fig. I)..
Changes often occurred within 1 minute of injection, however, maximum increases were seen between 12.5+3.7
33 and 57 minutes after injection to
(mean + 1 SEM, n = 20) imp/set.
(~~0.05).
2. Short latency evoked responses The effects of RX77368 injection on the short latency responses of 8 VBT neurones to peripheral
stimulation was determined.
A reduction in
the latency of response was observed in 6 of the neurones 5.27kO.48 msec before injection to 4.80+0.43
from
(mean + 1 SEM, n = 8,
p
msec after injection.
histogram
is shown for one of the units in Fig. 2.
A post-stimulus
latency Two neurones were
unaffected.
3
b. .I
0
6
Tlmetmsec)
Figure 2. Post-stimulus
histograms
of a VBT neurone, before RX773bS.
0
10
6
of short-latency
(left) and after
I
Tlmefmsec)
10
evoked discharges
(right) injection of
Each plot built from responses to 128 consecutive
stimuli.
3. Long latency responses The effects of RX77368 injection on long latency evoked responses were observed in 8 VBT neurones.
In 5 of the 8 units there were no
long latency responses present prior to injection.
In the remaining
three, discharges were produced between 75 and 250 msec after stimulation. particular producing
However, there was no evidence to suggest that any
latency within this range was particularly discharges.
favourable
After RX77368 injection, however,
34
for
5 of the 8
units developed rhythmically
Figure 3. Post-stimulus of a VBT neurone, before
repeated discharges
(Fig. 3).
histograms of long latency evoked discharges (left) and after
(right), injection of
Each plot is built from the responses to 128 consecutive
RX77368. stimuli.
Four of the five units produced a burst of discharges within the range 88.8 to 98.1
(mean = 94.0) msec after stimulation,
a burst of discharges
in the range 133.2 to 144.8 (mean = 140.2) msec
and four of the five a burst of discharges 205.6
three of the five
(mean = 198.0) msec.
in the range 184.6 to
In the remaining three units, rhythmicity
did not develop. 4. Somatosensory Measurements
cortical evoked responses
of the somatosensory
experiments.
Reductions
evoked potential were made in five
in the latencies and increases in the
amplitudes of both the Pl and Nl waves were observed
(Table 1 and
Fig. 4). Pl Before After
RX RX
Latency
6.2 (0.2) 5.7 (0.17)*
Nl
Latency
Pl
Amplitude
1.6 (0.2)
100
7.2 (0.14)
(35.4)
178
Table 1. Latency to peaks of Pl and Nl waves. + 1 SEM, n = 5.
Amplitude 100
223
(41.9)X
Each figure is the mean
Also shown are the peak amplitudes of these waves,
expressed as a % of control value. control values
Nl
(~~0.05)
Significant
shown by *.
35
differences
from
r-----l. -\ i---> / \ ‘1_ ,-$-$ r-.?,? i, /
I
0
Tlmetmsec)
Figure 4. Post-stimulus (upper) and after
2k before
averaged cortical evoked potential,
Each average is
(lower), injection of RX77368.
built from the responses to 128 consecutive
stimuli.
Vertical
calibration bar is 100 UV. DISCUSSION It has been demonstrated
in these experiments
that systemic injection
of RX77368 produces an increase in excitability
of neurones in the
VBT as measured by their decrease in latency to a peripheral stimulus.
It is not possible
from ,the present experiments
to
determine whether or not this is as a result of direct effects on the VBT.
Ionophoretic
both excitatory
studies on neurones
in thalamic nuclei have shown
(15) and inhibitory effects
size or synchrony of the cuneothalamic
(16).
An increase in the
volley would seem to be
unlikely since cuneate neurones are either unaffected ionophoresis
of TRB
or inhibited by
(17).
Increases in the incidence of later, rhythmic discharges were also observed after RX77368 injection taking the form of bursts of impulses occurring within particular post-stimulus 94,140 and 198ms.
latency windows at around
This effect on thalamic rhythmicity
in view of the observation
is interesting
(7) that neurones in the septum which are
rhythmically
active are more often excited by TRB than are non-
rhythmically
active neurones.
The observation
of increased spontaneous
activity of neurones in the
VBT indicates that the changes in excitability
36
are not just phasic
changes associated with the processing
of the input volley but due to
rather more tonic changes in excitability. Increases in both the Pl and Nl waves of the somatosensory potential were observed.
The increase in the Pl wave is compatible volley, though it is not possible
with an increased thalamocortical to determine
evoked
from the present experiments whether the elevated Nl
wave occurs as a result of the increased input or whether there are additional effects on the cerebral cortex or other cortical inputs. Iontophoretic
studies have produced
little agreement on the effects
of TRH on single neurones in the cerebral cortex. failed to demonstrate effects
a direct effect
(8,18,19),othersexcitatory
(6,15) and others inhibition
consistent observation
(16,171.
excitatory
formation modulate
(6,8,18,19).
Since powerful
of the VBT
(Zl), the possibility
of a cholinergic mechanism by RX77368 in the
of increased excitability
present experiments,
reticular
(20) and since neurones in the reticular
the excitability
exists for potentiation
produces
of cholinergic
cholinergic pathways exist between the brainstem
formation and the VBT
production
However, a more
has been the potentiation
excitation of cortical cells by TRH
Some studies have
of VBT cells.
Thus in the
it has been shown that the TRH analogue RX77368
increases in the excitability
of a sensory input system whicl-
is closely integrated with the motor output system. important consequences
This may have
on the ability to plan and execute motor
activity.
REFERENCES 1. Ervin, G., Schmitz, S.A., Nemeroff, C.B. et al (1981) Thyrotropin releasing hormone and amphetamine produce different patterns of behavioural
excitation
in rats.
European J. Pharmacol.,
72, 35-43
2. Metcalf, G., Dettmar, P-W., Fortune, D. et al (1982) Neuropharmacological thyrotropin
evaluation of RX77368 - a stabilised analogue of
releasing hormone
(TRH).
193-206
37
Regulatory Peptides,
3,
3. Webster, Y.A.D., Griffiths,
E.C. and Slater, P. (1982) Induction
of wet dog shaking in rats by analogues and metabolites thyrotrophin
releasing hormone
(TRH).
Regulatory
of
Peptides,
5,
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Received 27/9/85 Accepted 15/10/8S
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to
Progress in