Importance of Polysynaptic Inputs and Horizontal Connectivity in the Generation of Tetanus-Induced Long-Term Potentiation in the Rat Auditory Cortex

QUICK SEARCH:

	Author:		Keyword(s):
Year:		Vol:		Page:

HOME | SEARCH | ARCHIVE | SUBSCRIBE | CONTACT | HELP

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via Web of Science (35)

Citing Articles via Google Scholar

Google Scholar

Articles by Kudoh, M.

Articles by Shibuki, K.

Search for Related Content

PubMed

PubMed Citation

Articles by Kudoh, M.

Articles by Shibuki, K.

Previous Article  |  Next Article

Volume 17, Number 24, Issue of December 15, 1997

Importance of Polysynaptic Inputs and Horizontal Connectivity in the Generation of Tetanus-Induced Long-Term Potentiation in the Rat Auditory Cortex

Masaharu Kudoh and Katsuei Shibuki
Department of Neurophysiology, Brain Research Institute, Niigata University, Niigata 951, Japan

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Supragranular pyramidal neurons in the adult rat auditory cortex (AC) show marked long-term potentiation (LTP) of populationspikes after tetanic white matter stimulation (TS). For determinationof whether this marked LTP is specific to AC, LTP in rat AC sliceswas compared with LTP in slices of the visual cortex (VC). Theamplitude of TS-induced LTP in AC was twice that in VC. LTP ofEPSPs was also studied with perforated patch or whole-cell recording.Although the amplitude of TS-induced LTP of EPSPs in AC was largerthat in VC, no cortical difference was found in LTP elicited bylow-frequency stimulation paired with current injection. NeocorticalLTP is dependent on the activation of NMDA receptors, and inductionof LTP requires postsynaptic depolarization for removal of Mg²⁺ blockade of NMDA receptors. The postsynaptic depolarization elicitedby TS in supragranular pyramidal neurons in AC was significantlylarger than that in VC. Cutting of supragranular horizontal connectionsresulted in a decrease in the depolarization amplitude in AC butan increase in the depolarization amplitude in VC. The corticaldifference in TS-induced LTP was diminished in the slices in whichhorizontal connections in supragranular layers were cut. The estimateddensity of horizontal axon collaterals of supragranular pyramidalneurons in AC was approximately twice that in VC. These resultsstrongly suggest that the marked polysynaptic and postsynapticdepolarization during TS and the resulting marked LTP in AC areattributed to well developed horizontal axon collaterals of supragranularpyramidal neurons in AC.
Key words: auditory cortex; long-term potentiation; pyramidal neuron; axon collateral; horizontal connection; visual cortex

INTRODUCTION

Experience-dependent synaptic plasticity is required for development of the primary sensory cortex (Hubel and Wiesel, 1963;Wiesel and Hubel 1963; Blakemore and Cooper, 1970; Hirsch andSpinelli 1970; Woolsey and Wann, 1976). Long-term potentiation(LTP) of thalamocortical synapses is elicited in young animals(Crair and Malenka, 1995). Cortical LTP in young animals is thoughtto serve as a cellular mechanism for developmental plasticity(Kirkwood et al., 1995). LTP of intracortical circuits is elicitedin adult animals (Iriki et al., 1989; Hirsch and Gilbert, 1993;Hess and Donoghue, 1994). Neocortical LTP is usually dependenton the activation of NMDA receptors (Artola and Singer, 1987;Kimura et al., 1989), and postsynaptic depolarization is requiredfor the induction of LTP to remove Mg²⁺ blockade of NMDA receptors (Norwak et al., 1984; Artola et al.,1990). Postsynaptic depolarization is also required for inducingthe plasticity of neural responsiveness in visual cortex (VC)(Frégnac et al., 1992; Shultz and Frégnac, 1992) and in auditorycortex (AC) (Cruikshank and Weinberger, 1996).

It has been reported that the extents of neocortical LTP and postsynaptic depolarization during induction of LTP are differentbetween the motor and somatosensory cortices (Castro-Alamancoset al., 1995; Castro-Alamancos and Connors, 1996). Therefore,it is quite likely that functional characteristics of each cortexare reflected in the diversity of synaptic plasticity. In AC ofadult animals, the receptive field properties of single neuronschange on sound discrimination learning (e.g., Edeline and Weinberger,1993), and the cortical region responding to tones of the frequencyused enlarges (Recanzone et al., 1993). Synaptic connections betweenauditory cortical neurons are potentiated by correlated activitiesduring learning (Ahissar et al., 1992). A short auditory experienceelicits synaptic plasticity in AC, by which the sound discriminationability of rats is enhanced (Sakai et al., 1995, 1996). MarkedLTP of population spikes is observed in AC of adult rats (Kudohand Shibuki, 1994, 1996a). These many findings raise the possibilitythat AC of adult animals may be specialized to produce markedsynaptic plasticity.

Pyramidal neurons are connected to each other via axon collaterals (Thomson and Deuchars, 1994), and thalamocortical inputsare amplified by excitatory recurrent circuits (Douglas et al.,1995). During presentation of a species-specific vocalization,synchronized neural activities are recorded from a wide area ofAC of the common marmoset (Wang et al., 1995). Correlated activitiesbetween a pair of neurons are detected in AC during presentationof auditory stimuli (deCharms and Merzenich, 1996). Well developedconnections between pyramidal neurons, the presence of which inAC are expected based on these findings, may play a critical rolein amplification of postsynaptic depolarization and inductionof synaptic plasticity. Therefore, we compared LTP between ACand VC and studied the relationship between the diversity of LTPand that of intracortical circuits.

Preliminary results have been published in abstract form (Kudoh and Shibuki, 1996b).

MATERIALS AND METHODS
Materials. Wistar rats of both sexes (4-7 weeks old) were used. After a rat was anesthetized with ether, it was immersed inice-cold water except for the nose for 3 min to reduce brain temperature.Immediately after decapitation, the brain was removed in an ice-coldartificial medium bubbled with 95% O₂ and 5% CO₂. The compositionof the medium (in mM) was NaCl 124, KCl 5, NaH₂PO₄ 1.24, MgSO₄1.3, CaCl₂ 2.4, NaHCO₃ 26, and glucose 10. AC was determined asarea 41 (Krieg, 1964) or area 1 of the temporal cortex (Zilles,1985), and a block including AC was dissected out (see Fig. 1A).Coronal slices (thickness, 400 µm) were prepared from the blockwith a microslicer (DTK-2000; Dosaka, Osaka, Japan). For comparison,coronal slices were prepared from VC (see Fig. 1A), which wasidentified as area 17 (Krieg, 1964) or area 1 of the occipitalcortex (Zilles, 1985). In some experiments, slices cut in a planeorthogonal to the coronal plane and the surface of the cortexwere prepared from AC and VC, respectively. The obtained sliceswere incubated in an artificial medium at 30°C for at least 1hr before recording. The recording was performed at 35°C unlessotherwise specified. During the recording, the slices were continuouslyperfused with the oxygenated medium at a flow rate of 1 ml/min.In some experiments, various drugs were added to the perfusingmedium. 6-Cyano-7-nitroquinoxaline-2,3-dione (CNQX) and D-( $-$ )-2-amino-5-phosphonovalerate(D-APV) were obtained from Tocris Cookson (Bristol, UK). Bicucullinewas purchased from Research Biochemicals (Natick, MA). The experimentswere performed according to the guidelines of Niigata Universityand had the approval of the ethics committee of Niigata University.
Fig. 1. Supragranular field potentials elicited by single-pulse stimulation and TS-induced LTP in AC and VC. A, Diagram showing ACand VC. Solid lines in AC and VC represent the planes from whichslices were prepared. B, Field potentials in AC. Three tracesare superimposed, which were recorded in normal medium, in Mg²⁺-free medium containing 10 µM CNQX, and in Mg²⁺-free medium containing CNQX and 50 µM D-APV. C, Field potentialsin VC. The three traces were recorded under the same conditionsas in B. D, Field potential traces in AC recorded before and after(*) TS. Note the potentiation evoked in the trans-synaptic componentof field potentials selectively. Two traces elicited every 30sec were averaged to estimate the field potentials. E, Field potentialsin VC recorded before and after (*) TS. F, Time course of LTPin AC (filled circles) and VC (open circles). Mean and SEM areshown. Numbers of the experiments are shown in parentheses. G,Amplitude of LTP in AC (hatched bars) and VC (open bars) elicitedby TS in coronal slices (TS) or in the slices orthogonal to thecoronal plane (TS*). LTP elicited in the coronal slices by $theta$ -burststimulation ( $theta$ -burst) or by TS in the presence of bicuculline(0.5 µM; BIC) is shown. Asterisks represent significant differences(p < 0.01 or 0.05) between AC and VC.
[View Larger Version of this Image (39K GIF file)]

Stimulation. As a stimulating electrode, the cut end of a Teflon-coated Pt wire (metal diameter, 50 µm) was placed on theborder between the white matter and layer VI. An electrolyticallypolished Ag wire, which was insulated with polyvinyl chlorideexcept for the tip, was also used as a stimulating electrode andinserted into the border between the white matter and layer VI.In some experiments, supragranular layers were stimulated withthese electrodes. Biphasic pulses (duration of each phase of eachpulse, 100 µsec) were passed through the electrode to minimizestimulus artifacts in the recording. The intensity of pulses ineach phase was 600 µA for field potential recording unless otherwisespecified. For whole-cell or perforated patch recording, the intensityof the stimuli was 150 µA-1 mA. For evoking LTP in field potentials,tetanic white matter stimulation (TS; 100 pulses at 100 Hz, twiceat a 30 sec interval) or $theta$ -burst stimulation (four pulses at 100Hz, five pulse trains at 5 Hz, repeated five times at 0.1 Hz)was applied to the white matter. For evoking LTP in EPSPs of pyramidalneurons, TS (100 pulses at 100 Hz, 500 µA) was used. Low-frequencywhite matter stimulation (100 pulses at 2 Hz, 150 µA) paired withinjection of depolarizing current (1.5 nA, 100 msec) was alsoused to elicit LTP in EPSPs. In this experiment, a stimulus pulsewas applied to the white matter 50 msec after initiation of thecurrent injection for 100 msec.

Field potential recording. Field potentials elicited by white matter stimulation or supragranular focal stimulation were recordedthrough an electrolytically polished Ag wire, which was insulatedwith polyvinyl chloride except for the tip. After being passedthrough a bandpass filter between 0.2 Hz and 10 kHz, the datawere stored in a computer for later analysis. In some experimentsperformed using bicuculline (0.5 µM), the stimulus intensity wasreduced to 300-400 µA for adjustment of the amplitude of fieldpotentials, and additional currents were applied during TS throughanother stimulating electrode close to the other to give a totalcurrent of 600 µA.

Whole-cell or perforated patch recording. Supragranular pyramidal neurons were recorded using a blind slice patch techniquesimilar to the one described previously (Kudoh and Shibuki, 1996a).A glass micropipette was filled with a solution containing (inmM): K-gluconate 130, KCl 10, HEPES 10, EGTA 1 (or 0.5 for recordingLTP), MgCl₂ 1, Na-ATP 4, Na-GTP 1, and sucrose 16, with pH adjustedto 7.2 with KOH (resistance, 20-30 M $Omega$ ). This electrode was insertedinto supragranular layers, and a positive pressure of ~30 mmHgwas applied in the pipette during insertion. After a sudden increasein the access resistance of the electrode, negative pressure wasapplied to obtain whole-cell current-clamp recording.

For recording LTP in a pyramidal neuron, perforated patch recording was also used. The composition of the filling medium was(in mM): K₂SO₄ 92, KCl 31, HEPES 10, and MgCl₂ 1, adjusted topH 7.4 with KOH. The resistance of the recording electrode was8-12 M $Omega$ . Amphotericin B (Wako Chemicals) dissolved in dimethylsulfoxide(10 mg/ml) was added to the patch medium (final concentration,50 µg/ml). The tip was filled with an amphotericin B-free mediumto facilitate the sealing between the pipette and cell membrane.Membrane resistance and resting membrane potential were measured,and neurons with a resting membrane potential more negative than $-$ 55 mV were selected. Pyramidal neurons were identified in termsof an antidromic spike elicited by white matter stimulation atan intensity $<=$ 1 mA (Kudoh and Shibuki, 1996a). The recording wasperformed at 30°C for LTP experiments and at 35°C for other experiments.

RESULTS

Comparison of synaptic responses elicited by single-pulse stimulation
Before study of the diversity of LTP, synaptic responses elicited by single-pulse stimulation were compared between AC andVC. The field potentials elicited by white matter stimulationin supragranular layers of AC are composed of early and late negativewaves (Fig. 1B). The early negativity was resistant to 10 µM CNQX,an antagonist of non-NMDA glutamate receptors, whereas the latenegativity was blocked by CNQX as described previously (Kudohand Shibuki, 1994). This CNQX-sensitive negativity correspondsto trans-synaptically activated population spikes of pyramidalneurons (Kudoh and Shibuki, 1996a). These two components wererecorded in both cortices (Fig. 1B,C). The amplitude of the CNQX-resistantor CNQX-sensitive component was separately measured in AC (2.08± 0.17 and 0.85 ± 0.08 mV, mean ± SEM; n = 15) and in VC (2.07± 0.19 and 0.92 ± 0.09 mV; n = 11). However, no significant differencebetween AC and VC was found regarding the amplitude of each component.The third component appeared in an Mg²⁺-free medium containing 10 µM CNQX (Fig. 1B,C). The third componentwas blocked by 50 µM D-APV, an antagonist of NMDA receptors. Theamplitude of this D-APV-sensitive component in AC (0.63 ± 0.11mV; n = 5) was not significantly different from that in VC (0.68± 0.16 mV; n = 5).

The difference in synaptic responses between the cortices was analyzed using whole-cell current-clamp recording. The restingmembrane potential was $-$ 61 ± 1 mV (n = 25), and the membrane resistancewas 45 ± 3 M $Omega$ in the supragranular pyramidal neurons in AC, whereasthese parameters were $-$ 61 ± 1 mV (n = 26) and 43 ± 2 M $Omega$ , respectively,in VC. For comparison of the amplitudes of EPSPs that did notaccompany antidromic spikes, white matter was weakly stimulatedat an intensity of 150 µA. The rate of rise of EPSP amplitudewas 1.8 ± 0.2 V/sec (n = 17) in AC and 2.1 ± 0.2 V/sec (n = 16)in VC, and no significant difference between the cortices wasfound regarding these data.

Comparison of LTP between the cortices
LTP was compared in coronal slices of AC and VC. Only when the CNQX-resistant and trans-synaptic components of the field potentialselicited by the white matter stimulation at the intensity of 600µA were >1.5 and 0.5 mV, respectively, was analysis of LTP performed.As reported earlier (Kudoh and Shibuki, 1994), LTP in AC was selectivelyelicited by TS in the trans-synaptic population spikes, and theCNQX-resistant field potentials did not change on induction ofLTP (Fig. 1D). LTP was observed in the slices obtained from ratsof widely distributed ages (29-49 d postnatal), and no particularcritical period was found in this range of ages. Similarly, LTPwas recorded in VC, but the amplitude of this LTP was smallerthan that of the LTP in AC (Fig. 1E). The LTP amplitude was estimated30 min after cessation of TS. The value was 51 ± 8% (n = 15) inAC and 26 ± 5% (n = 11) in VC (Fig. 1F,G), and the differencewas statistically significant (Mann-Whitney U test, p < 0.01).

The observed diversity in TS-induced LTP might reflect a trivial difference in the recording conditions rather than a fundamentaldifference between the cortices. For investigation of this possibility,LTP recorded under various conditions was compared. First, LTPin AC and VC was recorded in horizontal and parasagittal slices,respectively. However, the amplitude of the LTP was not significantlydifferent from that of the LTP recorded in coronal slices (Fig.1G). The amplitude of LTP in horizontal slices of AC was twicethat of the LTP in parasagittal slices of VC (Fig. 1G), althoughthe difference in LTP amplitude between AC and VC was not statisticallysignificant in these slices. In coronal slices, LTP was also elicitedby $theta$ -burst stimulation or recorded in the presence of bicuculline(0.5 µM), an antagonist of GABA_A receptors, and a significantdifference in LTP amplitude between AC and VC was observed inboth experiments (p < 0.05; Fig. 1G).

We compared LTP in the rising slope of EPSPs with perforated patch recording from pyramidal neurons (Fig. 2A-C). The LTP amplitudewas estimated 10 min after cessation of TS, because recordingconditions in many neurons were stable within this period. Again,there was a significant difference (p < 0.05) in TS-induced LTPamplitude between AC (61 ± 10%; n = 8) and VC (23 ± 4%; n = 7).These results clearly indicate that there is a significant corticaldifference in TS-induced LTP amplitude, regardless of the methodused for recording LTP. However, when LTP was elicited by low-frequencywhite matter stimulation paired with injection of depolarizingcurrent (Fig. 2D-F), there was no apparent difference in the LTPamplitude between AC (32 ± 8%; n = 9) and VC (29 ± 8%; n = 9).Although no significant difference between the cortices was foundregarding the membrane resistance of pyramidal neurons, theseresults suggest a possibility that the cortical difference inTS-induced LTP may be attributed to that in the amplitude of depolarizationof pyramidal neurons during TS.
Fig. 2. LTP in the rising slope of EPSPs recorded in pyramidal neurons. A, EPSPs recorded before and after (*) TS in AC. The intensityof the test stimuli was 150 µA. B, EPSPs recorded before and after(*) TS in VC. C, Time course of TS-induced LTP in AC (filled circles)and in VC (open circles). Mean and SEM are shown. D, EPSPs recordedbefore and after (*) low-frequency stimulation paired with depolarizingcurrent injection in AC. E, EPSPs before and after (*) low-frequencystimulation plus depolarizing current injection in VC. F, Timecourse of LTP elicited by a combination of low-frequency stimulationand current injection in AC (filled circles) and in VC (open circles).In A-C, pyramidal neurons were recorded using a perforated patchtechnique. In D-F, a conventional whole-cell recording methodwas used.
[View Larger Version of this Image (29K GIF file)]

Diversity of polysynaptic and postsynaptic depolarization and roles of horizontal connections in the diversity
The diversity in TS-induced LTP between AC and VC suggests the presence of a difference in the extent of postsynaptic depolarizationduring TS. Therefore, we recorded supragranular pyramidal neuronswith whole-cell recording and measured the postsynaptic depolarizationduring TS (Fig. 3A). The maximal amplitude of the depolarizationduring TS was 50 ± 3 mV (n = 8) in AC, whereas it was 30 ± 1 mV(n = 10) in VC, and a significant difference was found betweenthe two values (p < 0.01; Fig. 3B).
Fig. 3. Depolarization of supragranular pyramidal neurons in response to TS (100 pulses at 100 Hz, 600 µA). A, Typical traces recordedin AC and VC are superimposed. The broken line shows the restingmembrane potential. B, Amplitudes of depolarization induced byTS in AC (hatched bars) and VC (open bars). The amplitudes ofdepolarization recorded in the slices in which the horizontalconnections in supragranular layers were interrupted by a pairof slits 450 µm apart are also shown. Pairs of data in which asignificant difference (p < 0.01 or 0.05, Mann-Whitney U test)was found are marked by asterisks.
[View Larger Version of this Image (25K GIF file)]

Because no significant difference between the cortices was found in the synaptic responses elicited by single-pulse stimulationor in the membrane resistance of pyramidal neurons, we expectedthat the diversity in the depolarization was attributable to polysynapticexcitation (Castro-Alamancos et al., 1995), which may be amplifiedin intrinsic neural circuits (Douglas et al., 1995). Possiblepathways responsible for the diversity in TS-induced LTP are recurrentexcitatory connections between pyramidal neurons through horizontalaxon collaterals. Therefore, horizontal connections were cut bymaking a pair of slits 450 µm apart in the supragranular layersof the slices. The slits were made using a razor blade attachedto a manipulator. The amplitude of the depolarization in AC wassignificantly reduced by the presence of the slits (p < 0.05;Fig. 3B), whereas that in VC was significantly augmented (p <0.05). These data suggest that the differences in the extent ofpolysynaptic and postsynaptic depolarization may be derived fromsynaptic inputs mediated by horizontal connections.

Roles of horizontal connections in diversity of TS-induced LTP
Because the difference in TS-induced depolarization of pyramidal neurons was diminished by the presence of a pair of slits,we cut supragranular horizontal connections by adding a pair ofslits and measured the amplitude of TS-induced LTP. The LTP amplitudein AC was significantly reduced by the presence of a pair of slits400 or 450 µm apart (Fig. 4A). However, no effect of adding slitswas observed in VC (Fig. 4B). The size of the gap between theslits was varied. The amplitude of LTP in AC was significantlyreduced by the presence of a pair of slits 400 or 450 µm apart(p < 0.05, respectively) but not 500 µm apart (Fig. 4C). The LTPin VC was not affected significantly by the presence of a pairof slits with any of the interslit gap sizes used, and therefore,no significant difference in LTP amplitude between AC and VC wasobserved in the slices with a pair of slits 400 or 450 µm apart.These data strongly support the hypothesis that horizontal connectionsplay a facilitative role in induction of TS-induced LTP in ACbut not in VC.
Fig. 4. Effects of the presence of a pair of slits made in the supragranular layers on TS-induced LTP. A, Time course of LTP in ACrecorded in the slices with or without a pair of slits 400 or450 µm apart (filled circles). TS was used to evoke LTP. ControlLTP is also shown (open circles). B, Time course of LTP recordedin VC with (filled circles) or without (open circles) a pair ofslits. C, The relationship between the interslit gap size (400-500µm) and the amplitude of LTP. Filled and open circles representdata recorded in AC and VC, respectively. Asterisks mark pairsof data in which a significant difference was found (p < 0.05).
[View Larger Version of this Image (29K GIF file)]

Horizontal spreading of trans-synaptic field potentials in supragranular layers
For study of synaptic responses mediated by horizontal connections in supragranular layers, recording and stimulating electrodeswere placed in supragranular layers, and horizontal spreadingof the field potentials in response to focal stimulation was recorded.CNQX-resistant and trans-synaptic components of the field potentialswere observed after the focal stimulation at an intensity of 300µA in both cortices (Fig. 5A). The distance between the stimulatingand recording electrodes was varied, and the relationship betweenthe distance and the amplitude of the trans-synaptic field potentialswas plotted (Fig. 5A). The potentials in AC were larger than thosein VC, and a significant difference in the amplitude (p < 0.05)was found at 400, 500, and 600 µm (Fig. 5A). For determinationof the contribution of intrinsic inhibition to the difference,field potentials were recorded in the presence of bicuculline(0.5 µM). Horizontal spreading of the trans-synaptic potentialswas facilitated by bicuculline (Fig. 5B). Although the effectof bicuculline was observed in both cortices, it was more pronouncedin VC than in AC, and no significant difference in the amplitudeof trans-synaptic responses between the cortices was observedin the presence of bicuculline (Fig. 5B).
Fig. 5. Horizontal spreading of trans-synaptic field potentials recorded in the supragranular layers after focal stimulation at 300µA. A, Relationship between the amplitude of the trans-synapticfield potentials and the distance between the recording and stimulatingelectrodes in AC (closed circles) and VC (open circles). Meanand SEM are shown. Asterisks represent significant differencesbetween AC and VC (p < 0.05). Insets, Traces of field potentialsrecorded in AC and VC. Arrowheads represent the trans-synapticfield potentials. The distance between the recording and stimulatingelectrodes was 300 µm. B, Data similar to those in A, recordedin the presence of bicuculline (0.5 µM). C, Horizontal spreadingof supragranular CNQX-resistant field potentials elicited by focalstimulation at 600 µA in AC. Relationship between the amplitudeof CNQX-resistant potentials and the distance between electrodesis plotted. Data recorded in the same slice are represented bythe same symbols connected by lines. Inset, Trace of field potentialsrecorded in the supragranular layers of AC. For blocking trans-synapticpotentials and subsequent activation of inhibitory neurons, recordingwas performed in the presence of 10 µM CNQX. D, Data similar tothose in C, recorded in VC.
[View Larger Version of this Image (43K GIF file)]

Horizontal spreading of CNQX-resistant potentials in supragranular layers
Although no clear difference in the trans-synaptic field potentials was found between AC and VC in the presence of bicuculline(Fig. 5B), a significant difference in TS-induced LTP amplitudebetween AC and VC was observed even in the presence of bicuculline(Fig. 1G). Therefore, we focused on horizontal spreading of CNQX-resistantfield potentials. We recorded the amplitude of the field potentialsin the presence of CNQX (10 µM; Fig. 5C,D). For evoking clearpotentials, focal stimulation at an intensity of 600 µA was used.The amplitude of the CNQX-resistant potentials in AC was largerthan that in VC. It was 2.1 ± 0.4 mV (n = 7) in AC and 1.3 ± 0.2mV (n = 9) in VC at a site 300 µm from the stimulating electrode,and the difference was significant (p < 0.05; Fig. 5C,D). TheCNQX-resistant field potentials are composed of presynaptic volleypotentials and antidromic population spikes. Therefore, it issuggested that the density of horizontal connections is higherin AC than in VC.

For confirmation of the difference in the density of horizontal connections, whole-cell recording was used. Focal stimulationof supragranular layers produced EPSPs in a typical supragranularpyramidal neuron in each cortex (Fig. 6). As the stimulus intensitywas increased, the amplitude of the EPSPs increased, and orthodromicspikes appeared. In some neurons, an antidromic spike appearedwithout a preceding EPSP (Fig. 6A). Of 35 supragranular pyramidalneurons recorded in AC, 18 showed antidromic spiking in responseto the 600 µA focal stimulation, whereas only 6 of 25 visual neuronsresponded antidromically. This difference in the ratio of neuronsshowing antidromic spiking between the cortices was significant( $chi$ ² test, p < 0.05). It is concluded from these results that thedensity of horizontal axon collaterals of pyramidal neurons inAC is approximately twice that in VC.
Fig. 6. Responses of supragranular pyramidal neurons elicited by focal stimulation of the supragranular layer 300 µm from the recordingelectrode. A, Traces recorded in AC. The stimulus intensity wasbetween 120 and 320 µA. The asterisk represents antidromic spikes.B, Data recorded in VC elicited by stimuli with an intensity of150-800 µA.
[View Larger Version of this Image (17K GIF file)]

DISCUSSION
In our previous study (Kudoh and Shibuki, 1996a), we found that most of supragranular pyramidal neurons recorded in AC slicesof adult rats showed marked TS-induced LTP in trans-synaptic spikingactivities, which correspond to cortical output to other corticalareas (Toyama et al., 1969). For determination of whether thismarked TS-induced LTP is specific to AC, we compared LTP betweenAC and VC in the present study and found that TS-induced LTP inAC was twice that in VC, whereas no cortical difference was foundin LTP of EPSPs elicited by low-frequency stimulation paired withcurrent injection. Results of analyses for the difference in TS-inducedLTP amplitude led us to conclude that polysynaptic and postsynapticdepolarization in pyramidal neurons of AC is amplified by activityof intrinsic local circuits composed of well developed horizontalaxon collaterals, and that marked TS-induced LTP in AC is attributableto the amplified postsynaptic depolarization during TS. The rationalefor this conclusion and possible functions of well developed horizontalconnections in AC are discussed below.

Linkage between TS-induced postsynaptic depolarization and TS-induced LTP
We tested various possibilities that might explain the cortical difference in TS-induced LTP amplitude. The possible technicalartifacts generated during preparation of the slices might producethe difference. However, TS-induced LTP amplitude recorded inhorizontal slices of AC and parasagittal slices of VC did notdiffer markedly from those recorded in coronal slices. It is alsounlikely that synaptic responses elicited by single-pulse stimulationdiffer significantly between the cortices. Although NMDA receptorsare quite important for evoking neocortical LTP in AC (Kudoh andShibuki, 1994, 1996a) and VC (Artola and Singer, 1987; Kimuraet al., 1989), no clear difference in the amplitude of the populationspikes elicited by activation of NMDA receptors was found betweenthe cortices. Diversity in intrinsic inhibition is another possibility,but the difference in TS-induced LTP was not diminished by bicuculline(Fig. 1G). However, no apparent cortical difference was foundin pairing-induced LTP of EPSPs (Fig. 2F). This finding stronglysupports the notion that the difference in TS-induced LTP is aresult of circuitry rather than biochemical differences. Similarly,the difference in TS-induced LTP cannot be explained by corticaldiversities in the critical period for the induction of LTP. Theremaining possibility is that the difference in TS-induced LTPis derived from differences in the extents of TS-induced postsynapticdepolarization. In the slices in which supragranular horizontalconnections were interrupted by a pair of slits, the differencein TS-induced LTP was diminished, and TS-induced depolarizationwas reduced in AC and augmented in VC. A causal linkage betweenthe TS-induced postsynaptic depolarization and TS-induced LTPis strongly suggested by these results.

Roles of horizontal axon collaterals of pyramidal neurons in generation of LTP diversity
TS-induced depolarization was reduced by the presence of slits in AC but was augmented in VC. Therefore, it is expected thatmore inhibitory neurons are activated by horizontally propagatinginputs in VC than in AC. This hypothesis is consistent with theobservation that the supragranular field potentials elicited byfocal stimulation were augmented by bicuculline, as shown previously(Chagnac-Amitai and Connors, 1989), and that the effect of bicucullineis more pronounced in VC than in AC (Fig. 5A,B). However, LTPin VC was not augmented by bicuculline or by cutting of horizontalconnections in the supragranular layers in the present study.This apparent discrepancy may be explained by the presence ofinhibitory inputs terminating on the soma and the initial segmentof pyramidal neurons (Williams et al., 1992). These inhibitoryinputs are expected to suppress spike generation regardless ofexcitatory dendritic inputs, whereas dendritic depolarizationand resulting LTP at excitatory synapses on remote dendrites arenot (Blomfield, 1974). The density of horizontal connections canbe estimated by measurement of CNQX-resistant potentials or antidromicunit activities of pyramidal neurons. The estimated density ofhorizontal connections differed significantly between AC and VC.Therefore, it is very likely that the density of horizontal axoncollaterals of pyramidal neurons is important in the amplificationof polysynaptic and postsynaptic depolarization and of TS-inducedLTP.

Critical density of horizontal axon collaterals required for amplification of polysynaptic and postsynaptic depolarization and of TS-induced LTP
Axon collaterals >1 mm are well developed in VC (Gilbert, 1992). However, an effect of cutting of horizontal connections onTS-induced LTP was observed only in AC. Auditory pyramidal neuronstend to extend long-range axon collaterals through isofrequencybands (Reale et al., 1983; Ojima et al., 1991), which extend throughthe dorsoventral axis in rats (Sally and Kelly, 1988). However,the amplitude of TS-induced LTP in the coronal slices parallelto the isofrequency bands did not differ significantly from thatin the horizontal slices cut orthogonally to the isofrequencybands. Therefore, long-range axon collaterals do not seem criticalfor TS-induced LTP. The slits, which caused a reduction in theamplitude of TS-induced LTP in AC, were <500 µm apart. Therefore,it is quite likely that axon collaterals located within 500 µmfrom the soma determine the amplitude of TS-induced LTP in AC.This range might correspond to the area where accumulation ofextracellular K⁺ is elicited by TS, and neural excitability is facilitated (Lenget al., 1988). However, this hypothesis does not explain the differencesin TS-induced LTP amplitude between AC and VC.

Alternatively, there might be a critical density of horizontal connections required for amplification of TS-induced LTP. Supragranularpyramidal neurons are connected to each other, and a single spikein the activity of one pyramidal neuron is sufficient to elicitmeasurable EPSPs in the target pyramidal neurons (Thomson et al.,1988; Mason et al., 1991). During TS, many pyramidal neurons areactivated simultaneously, so that mutual recurrent connectionsmay function as reverberating circuits. Such reverberating activitiesare observed in networks of cultured cortical neurons (Muramotoet al., 1993). Although long-lasting reverberating activity isunlikely to occur because of presynaptic depression and postsynapticdesensitization (Thomson and West, 1993), transient reverberationmay be produced during TS if the gain of mutual recurrent connectionsbetween pyramidal neurons is larger than unity. The density ofhorizontal connections in AC is higher than that in VC, and ahigh density of axon collaterals is expected to be present withina narrow area around the soma. TS-induced LTP seems to be amplifiedby local circuits located within a narrow area around the somain AC. This coincidence between the high density of connectionsand amplification of TS-induced LTP is explained by assuming thatthe density of connections around the soma in AC is larger thanthe critical density at which the gain of mutual recurrent connectionsbetween pyramidal neurons is unity.

Functional significance of local circuits specific to AC
In the present study, we found well developed horizontal axon collaterals of pyramidal neurons in slices of AC. Because mostof the local connections cut by the slicing are expected to beintact in vivo, characteristics of local circuits are expectedto be clearer in vivo than in slices. The well developed horizontalconnections in AC may have various functional implications. First,thalamocortical sensory inputs are amplified by recurrent intracorticalcircuits (Douglas et al., 1995), of which horizontal axon collateralsare main components. Well developed horizontal connections inAC, therefore, facilitate postsynaptic depolarization inducedby auditory inputs. Because postsynaptic depolarization is quiteimportant in cortical plasticity (Frégnac et al., 1992; Shultzand Frégnac, 1992; Cruikshank and Weinberger, 1996), synapticplasticity elicited by auditory inputs in vivo is probably facilitatedby horizontal connections, as TS-induced LTP in slices is amplified.This characteristic feature of AC may explain marked synapticplasticity elicited by learning in AC of adult animals (Ahissaret al., 1992; Edeline and Weinberger, 1993; Recanzone et al.,1993).

Intracortical connections between pyramidal neurons are expected to play an essential role in synchronized and oscillatoryactivities in the sensory cortex (Singer, 1993). Horizontal connectionsmay mediate synchronization of neural activities in AC. The synchronizedand oscillatory activities found in VC (Grey and Singer, 1989)have also been detected in AC by electrophysiological recording(Franowicz and Barth, 1995; Barth and MacDonald, 1996), opticalrecording (Fukunishi and Murai, 1995), and magnetic field recording(Tesche and Hari, 1993). Rhythmic activities may be generatedin a single cortical neuron (Llinás et al., 1991). However, extensivesynchronization between neurons requires the presence of welldeveloped horizontal connections. A logical question derived fromthis consideration is whether many neurons connected with welldeveloped horizontal axon collaterals in AC may simultaneouslyrespond to auditory stimuli. As expected, scattered distributionof excited neurons during presentation of auditory stimuli canbe observed in AC by optical recording (Fukunishi et al., 1992;Taniguchi et al., 1992). In contrast, high-resolution images ofneural populations excited by visual stimuli in VC can be obtainedthrough optical recording (Frostig et al., 1990; Bonhoeffer andGrinvald, 1991). These results suggest that neurons connectedwith well developed axon collaterals in AC might be suitable substratesfor population coding of auditory information (Wang et al., 1995).

FOOTNOTES

Received Aug. 8, 1997; revised Sept. 29, 1997; accepted Sept. 30, 1997.

This work was supported by grants from the Japanese Government, Toyota RIKEN, the Uehara Foundation, and the Nissan ScienceFoundation. We thank T. Bando and H. Nawa for reading this manuscriptand Y. Tamura and N. Taga for technical assistance.

Correspondence should be addressed to Katsuei Shibuki, Department of Neurophysiology, Brain Research Institute, Niigata University,1 Asahi-machi, Niigata 951, Japan.

REFERENCES

Ahissar E, Vaadia E, Ahissar M, Bergman H, Arieli A, Abeles M (1992) Dependence of cortical plasticity on correlated activity of single neurons on behavioral context. Science 257:1412-1415[Abstract/Free Full Text].
Artola A, Singer W (1987) Long-term potentiation and NMDA receptors in rat visual cortex. Nature 330:649-652[Medline].
Artola A, Bröcher S, Singer W (1990) Different voltage-dependent thresholds for inducing long-term depression and long-term potentiation in slices of rat visual cortex. Nature 347:69-72[Medline].
Barth DS, MacDonald KD (1996) Thalamic modulation of high-frequency oscillating potentials in auditory cortex. Nature 383:78-81[Medline].
Blakemore C, Cooper GF (1970) Development of the brain depends on the visual environment. Nature 228:477-478[Medline].
Blomfield S (1974) Arithmetical operations performed by nerve cells. Brain Res 69:115-124[Web of Science][Medline].
Bonhoeffer T, Grinvald A (1991) Iso-orientation domains in cat visual cortex are arranged in pinwheel-like patterns. Nature 353:429-431[Medline].
Castro-Alamancos MA, Connors BW (1996) Short-term synaptic enhancement and long-term potentiation in neocortex. Proc Natl Acad Sci USA 93:1335-1339[Abstract/Free Full Text].
Castro-Alamancos MA, Donoghue JP, Connor BW (1995) Different forms of synaptic plasticity in somatosensory and motor areas of the neocortex. J Neurosci 15:5324-5333[Abstract].
Chagnac-Amitai Y, Connors BW (1989) Horizontal spread of synchronized activity in neocortex and its control by GABA-mediated inhibition. J Neurophysiol 61:747-758[Abstract/Free Full Text].
Crair MC, Malenka RC (1995) A critical period for long-term potentiation at thalamocortical synapses. Nature 375:325-328[Medline].
Cruikshank SJ, Weinberger NM (1996) Receptive-field plasticity in the adult auditory cortex induced by Hebbian covariance. J Neurosci 16:861-875[Abstract/Free Full Text].
deCharms RC, Merzenich MM (1996) Primary cortical representation of sounds by the coordination of action-potential timing. Nature 381:610-613[Medline].
Douglas RJ, Koch C, Mahowald M, Martin KAC, Suarez HH (1995) Recurrent excitation in neocortical circuits. Science 269:981-985[Abstract/Free Full Text].
Edeline JM, Weinberger NM (1993) Receptive field plasticity in the auditory cortex during frequency discrimination training: selective retuning independent of task difficulty. Behav Neurosci 107:82-103[Web of Science][Medline].
Franowicz MN, Barth DS (1995) Comparison of evoked potentials and high-frequency (gamma-band) oscillating potentials in rat auditory cortex. J Neurophysiol 74:96-112[Abstract/Free Full Text].
Frégnac Y, Shultz D, Thorpe S, Bienenstock E (1992) Cellular analogs of visual cortical epigenesis. I. Plasticity of orientation selectivity. J Neurosci 12:1280-1300[Abstract].
Frostig RD, Lieke EE, Ts'o DY, Grinvald A (1990) Cortical functional architecture and local coupling between neuronal activity and the microcirculation revealed by in vivo high-resolution optical imaging of intrinsic signals. Proc Natl Acad Sci USA 87:6082-6086[Abstract/Free Full Text].
Fukunishi K, Murai N (1995) Temporal coding in the guinea-pig auditory cortex as revealed by optical imaging and its pattern-time-series analysis. Biol Cybern 72:463-473[Web of Science][Medline].
Fukunishi K, Murai N, Uno H (1992) Dynamic characteristics of the auditory cortex of Guinea pigs observed with multichannel optical recording. Biol Cybern 67:501-509[Web of Science][Medline].
Gilbert CD (1992) Horizontal integration and cortical dynamics. Neuron 19:1-13.
Grey CM, Singer W (1989) Stimulus-specific neuronal oscillations in orientation columns of cat visual cortex. Proc Natl Acad Sci USA 86:1698-1702[Abstract/Free Full Text].
Hess G, Donoghue JP (1994) Long-term potentiation of horizontal connections provides a mechanism to reorganize cortical motor maps. J Neurophysiol 71:2543-2547[Abstract/Free Full Text].
Hirsch HVB, Spinelli DN (1970) Visual experience modifies distribution of horizontally and vertically oriented receptive fields in cats. Science 168:869-871[Abstract/Free Full Text].
Hirsch JA, Gilbert CD (1993) Long-term changes in synaptic strength along specific intrinsic pathways in the cat visual cortex. J Physiol (Lond) 461:247-262[Abstract/Free Full Text].
Hubel DH, Wiesel TN (1963) Receptive fields of cells in striate cortex of young, visually inexperienced kittens. J Neurophysiol 26:994-1002[Free Full Text].
Iriki A, Pavlides C, Keller A, Asanuma H (1989) Long-term potentiation in the motor cortex. Science 245:1385-1387[Abstract/Free Full Text].
Kimura F, Nishigori A, Shirokawa T, Tsumoto T (1989) Long-term potentiation and N-methyl-D-aspartate receptors in the visual cortex of young rats. J Physiol (Lond) 414:125-144[Abstract/Free Full Text].
Kirkwood A, Lee H-K, Bear MF (1995) Co-regulation of long-term potentiation and experience-dependent synaptic plasticity in visual cortex by age and experience. Nature 375:328-331[Medline].
Krieg WJS (1964) Connections of the cerebral cortex. J Comp Neurol 84:221-323.
Kudoh M, Shibuki K (1994) Long-term potentiation in the auditory cortex of adult rats. Neurosci Lett 171:21-23[Web of Science][Medline].
Kudoh M, Shibuki K (1996a) Long-term potentiation of supragranular pyramidal outputs in the rat auditory cortex. Exp Brain Res 110:21-27[Web of Science][Medline].
Kudoh M, Shibuki K (1996b) LTP facilitated by extensive horizontal connections in the auditory cortex. Neurosci Res [Suppl] 20:S160.
Leng G, Shibuki K, Way SA (1988) Effects of raised extracellular potassium on the excitability of, and hormone release from, the isolated rat neurohypophysis. J Physiol (Lond) 99:591-605.
Llinás RR, Grace AA, Yarom Y (1991) In vitro neurons in mammalian cortical layer 4 exhibit intrinsic oscillatory activity in the 10- to 50-Hz frequency range. Proc Natl Acad Sci USA 88:897-901[Abstract/Free Full Text].
Mason A, Nicoll A, Stratford K (1991) Synaptic transmission between individual pyramidal neurons of the rat visual cortex in vitro. J Neurosci 11:72-84[Abstract].
Muramoto K, Ichikawa M, Kawahara M, Kobayashi K, Kuroda Y (1993) Frequency of synchronous oscillations of neural activity increases during development and is correlated to the number of synapses in cultured cortical neuron networks. Neurosci Lett 163:163-165[Web of Science][Medline].
Norwak L, Bregestovski P, Ascher P, Herbet A, Prochiantz A (1984) Magnesium gates glutamate-activated channels in mouse central neurons. Nature 307:462-465[Medline].
Ojima H, Honda CN, Jones EG (1991) Patterns of axon collateralization of identified supragranular pyramidal neurons in the cat auditory cortex. Cereb Cortex 1:80-94[Abstract/Free Full Text].
Reale RA, Brugge JF, Feng JZ (1983) Geometry and orientation of neural processes in cat primary auditory cortex (AI) related to characteristic-frequency maps. Proc Natl Acad Sci USA 80:5449-5453[Abstract/Free Full Text].
Recanzone GH, Schreiner CE, Merzenich MM (1993) Plasticity in the frequency representation of primary auditory cortex following discrimination training in adult owl monkeys. J Neurosci 13:87-103[Abstract].
Sakai M, Kudoh M, Shibuki K (1995) A quick test for sound discrimination ability of rats in a single session after preparatory training. Neurosci Res 21:273-276[Web of Science][Medline].
Sakai M, Kudoh M, Shibuki K (1996) Fixation of enhanced sound discrimination ability in the rat. Neurosci Res [Suppl] 20:S238.
Sally SL, Kelly JB (1988) Organization of auditory cortex in the albino rat: Sound frequency. J Neurophysiol 59:1627-1638[Abstract/Free Full Text].
Shultz D, Frégnac Y (1992) Cellular analogs of visual cortical epigenesis. II. Plasticity of binocular integration. J Neurosci 12:1301-1318[Abstract].
Singer W (1993) Synchronization of cortical activity and its putative role in information processing and learning. Annu Rev Physiol 55:349-374[Web of Science][Medline].
Taniguchi I, Horikawa J, Moriyama T, Nasu M (1992) Spatio-temporal pattern of frequency representation in the auditory cortex of guinea pigs. Neurosci Lett 146:37-40[Web of Science][Medline].
Tesche C, Hari R (1993) Independence of steady-state 40-Hz response and spontaneous 10-Hz activity in the human auditory cortex. Brain Res 629:19-22[Web of Science][Medline].
Thomson AM, Deuchars J (1994) Temporal and spatial properties of local circuits in neocortex. Trends Neurosci 17:119-126[Web of Science][Medline].
Thomson AM, West DC (1993) Fluctuations in pyramid-pyramid excitatory postsynaptic potentials modified by presynaptic firing pattern and postsynaptic membrane potential using paired intracellular recordings in rat neocortex. Neuroscience 54:329-346[Web of Science][Medline].
Thomson AM, Girdlestone D, West DC (1988) Voltage-dependent currents prolong single axon postsynaptic potentials in layer III pyramidal neurons in rat neocortical slices. J Neurophysiol 60:1896-1907[Abstract/Free Full Text].
Toyama K, Matsunami K, Ohno T (1969) Antidromic identification of association, commissural and corticofugal efferent cells in cat visual cortex. Brain Res 14:513-517[Web of Science][Medline].
Wang X, Merzenich MM, Beitel R, Schreiner CE (1995) Representation of a species-specific vocalization in the primary auditory cortex of the common marmoset: temporal and spectral characteristics. J Neurophysiol 74:2685-2706[Abstract/Free Full Text].
Wiesel TN, Hubel DH (1963) Single-cell responses in striate cortex of kittens deprived of vision in one eye. J Neurophysiol 26:1003-1017[Free Full Text].
Williams SM, Goldman-Rakic PS, Leranth C (1992) The synaptology of parvalbumin-immunoreactive neurons in the primate prefrontal cortex. J Comp Neurol 320:353-369[Web of Science][Medline].
Woolsey TA, Wann JR (1976) Areal changes in mouse cortical barrels following vibrissal damage at different postnatal ages. J Comp Neurol 170:53-66[Web of Science][Medline].
Zilles K (1985) In: The cortex of the rat. Berlin: Springer.

Copyright ©1997 Society for Neuroscience   0270-6474/1997/179458-08$05.00/0

This article has been cited by other articles:

H. Xu, V. C. Kotak, and D. H. Sanes
Normal Hearing Is Required for the Emergence of Long-Lasting Inhibitory Potentiation in Cortex
J. Neurosci., January 6, 2010; 30(1): 331 - 341.
[Abstract] [Full Text] [PDF]

V. C. Kotak, A. D. Breithaupt, and D. H. Sanes
Developmental hearing loss eliminates long-term potentiation in the auditory cortex
PNAS, February 27, 2007; 104(9): 3550 - 3555.
[Abstract] [Full Text] [PDF]

W. Ji, N. Suga, and E. Gao
Effects of Agonists and Antagonists of NMDA and ACh Receptors on Plasticity of Bat Auditory System Elicited by Fear Conditioning
J Neurophysiol, August 1, 2005; 94(2): 1199 - 1211.
[Abstract] [Full Text] [PDF]

M. B. Calford, L. L. Wright, A. B. Metha, and V. Taglianetti
Topographic Plasticity in Primary Visual Cortex Is Mediated by Local Corticocortical Connections
J. Neurosci., July 23, 2003; 23(16): 6434 - 6442.
[Abstract] [Full Text] [PDF]

K. Shibuki, R. Hishida, H. Murakami, M. Kudoh, T. Kawaguchi, M. Watanabe, S. Watanabe, T. Kouuchi, and R. Tanaka
Dynamic imaging of somatosensory cortical activity in the rat visualized by flavoprotein autofluorescence
J. Physiol., June 15, 2003; 549(3): 919 - 927.
[Abstract] [Full Text] [PDF]

M. Kudoh, M. Sakai, and K. Shibuki
Differential Dependence of LTD on Glutamate Receptors in the Auditory Cortical Synapses of Cortical and Thalamic Inputs
J Neurophysiol, December 1, 2002; 88(6): 3167 - 3174.
[Abstract] [Full Text] [PDF]

M. Sakai and N. Suga
Centripetal and centrifugal reorganizations of frequency map of auditory cortex in gerbils
PNAS, May 14, 2002; 99(10): 7108 - 7112.
[Abstract] [Full Text] [PDF]

S. J. Cruikshank, H. J. Rose, and R. Metherate
Auditory Thalamocortical Synaptic Transmission In Vitro
J Neurophysiol, January 1, 2002; 87(1): 361 - 384.
[Abstract] [Full Text] [PDF]

K. Seki, M. Kudoh, and K. Shibuki
Sequence dependence of post-tetanic potentiation after sequential heterosynaptic stimulation in the rat auditory cortex
J. Physiol., June 1, 2001; 533(2): 503 - 518.
[Abstract] [Full Text] [PDF]

H. Wakatsuki, H. Gomi, M. Kudoh, S. Kimura, K. Takahashi, M. Takeda, and K. Shibuki
Layer-specific NO dependence of long-term potentiation and biased NO release in layer V in the rat auditory cortex
J. Physiol., November 15, 1998; 513(1): 71 - 81.
[Abstract] [Full Text] [PDF]

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via Web of Science (35)

Citing Articles via Google Scholar

Google Scholar

Articles by Kudoh, M.

Articles by Shibuki, K.

Search for Related Content

PubMed

PubMed Citation

Articles by Kudoh, M.

Articles by Shibuki, K.