Neural Mechanisms of Task Failure During Sustained Submaximal Contractions

Williams, Petra S.

26 September 2013

No description available.

Neurosciences

Physiology

Rehabilitation

Neurology

neural mechanisms of fatigue

sustained submaximal contractions

transcranial magnetic stimulation TMS

cervicomedullary evoked potentials CMEP

supraspinal mechanisms of fatigue

Investigation of LTP-like Plasticity, Memory and Prefrontal Cortical Thickness: a TMS-EEG and Brain Imaging Study

Drodge, Jessica

04 January 2023

Introduction: Memory is a complex cognitive process formerly linked to mechanisms of brain plasticity that can be estimated in the left dorsolateral prefrontal cortex (DLPFC) using transcranial magnetic stimulation and electroencephalography (TMS-EEG). Also, cortical thickness in the DLPFC may be a potential proxy measure of brain plasticity as previous literature reports a link between better memory and thicker cortex. However, the link between brain plasticity and memory performance as well as DLPFC thickness remains to be clarified. Methods: Intermittent theta burst stimulation (iTBS) probed plasticity-like mechanisms in the left DLPFC in 17 cognitively healthy participants. TMS-EEG recordings were performed before and after sham and active iTBS to quantify plasticity via transcranial magnetic stimulation-evoked potentials (TEPs). Composite memory scores for each domain (verbal episodic, visual episodic and working memory) were obtained using the Cambridge Neuropsychological Test Automated Battery. Anatomical T1 images were acquired by magnetic resonance imaging and processed by open-source software (CIVET) and the Automated Anatomical Labeling atlas to extract cortical thickness of the DLPFC. All statistical analyses (linear mixed model, Tukey's post hoc test and Pearson's correlations) were completed in R Studio. Results: iTBS resulted in increased TEP amplitude P30 (F= 5.239, p = 0.029), as shown by a significant interaction between condition (iTBS, sham) and time (pre- and post-condition). Specifically, Tukey's post hoc test revealed that the P30 increase was near trending significant post-iTBS compared to pre-iTBS for the active condition (p = 0.166) but not for the sham condition (p = 0.294). A trending significant relationship was observed between the magnitude of P30 change post-iTBS and thicker left DLPFC (r = 0.488; p = 0.108). Lastly, no significant relationships between P30 change and memory performance were observed. Conclusion: These preliminary findings suggest there could be a relationship between increased capacity for brain plasticity and a thicker left DLPFC. To further investigate these relationships, we plan to recruit additional cognitively healthy participants. Our preliminary findings support the foundation for future clinical studies in which DLPFC thickness could be explored as a predictive factor for response to plasticity-targeting iTBS treatment.

Transcranial Magnetic Stimulation (TMS)

Electroencephalography (EEG)

Dorsolateral Prefrontal Cortex (DLPFC)

Healthy Subjects

Cortical Thickness

Impact d’une sieste sur plasticité cérébrale induite par stimulation magnétique transcrânienne

Sekerovic, Zoran

09 1900

Chez l’humain, différents protocoles de stimulation magnétique transcrânienne répétée (SMTr) peuvent être utilisés afin de manipuler expérimentalement la plasticité cérébrale au niveau du cortex moteur primaire (M1). Ces techniques ont permis de mieux comprendre le rôle du sommeil dans la régulation de la plasticité cérébrale. Récemment, une étude a montré que lorsqu’une première session de stimulation SMTr au niveau de M1 est suivie d’une nuit de sommeil, l’induction subséquente de la plasticité par une deuxième session SMTr est augmentée. La présente étude a investigué si ce type de métaplasticité pouvait également bénéficier d’une sieste diurne. Quatorze sujets en santé ont reçu deux sessions de intermittent theta burst stimulation (iTBS) connue pour son effet facilitateur sur l’excitabilité corticale. Les sessions de stimulation étaient séparées par une sieste de 90 minutes ou par une période équivalente d’éveil. L’excitabilité corticale était quantifiée en terme d’amplitude des potentiels évoqués moteurs (PEM) mesurés avant et après chaque session de iTBS. Les résultats montrent que la iTBS n’est pas parvenue à augmenter de manière robuste l’amplitude des PEMs lors de la première session de stimulation. Lors de la deuxième session de stimulation, la iTBS a produit des changements plastiques variables et ce peu importe si les sujets ont dormi ou pas. Les effets de la iTBS sur l’excitabilité corticale étaient marqués par une importante variabilité inter et intra-individuelle dont les possibles causes sont discutées. / In humans, various repetitive transcranial magnetic stimulation (rTMS) protocols can be used to modulate motor cortical plasticity. These techniques have shed light on the role of sleep in neural plasticity regulation. Recent work has demonstrated that when a night of sleep follows one session of rTMS over the hand motor cortex (M1), the capacity to induce subsequent plasticity by another rTMS session in M1 is enhanced. The present study investigated whether such metaplasticity could also benefit from a day nap. Fourteen healthy participants received two sessions of intermittent theta burst stimulation (iTBS) known for its excitatory effects on cortical excitability over M1 spaced by either a 90-minute nap or an equivalent amount of wake. Motor cortical excitability was measured in terms of amplitude of motor evoked potentials (MEP), which were assessed before iTBS and after the stimulation. Results show that the first iTBS session did not induce significant change in MEP amplitude. The second iTBS session induced variable plastic changes regardless of whether participants slept or stayed awake. The effects of iTBS on motor cortical excitability were highly variable within and between individuals. The possible causes of such variability are discussed.

Plasticité cérébrale

Sommeil

Sieste

Theta burst stimulation (TBS)

Métaplasticité

Variabilité

Humain

Plasticity

Sleep

Nap

Transcranial magnetic stimulation (TMS)

Metaplasticity

Variability

Human

Impact d’une sieste sur plasticité cérébrale induite par stimulation magnétique transcrânienne

Sekerovic, Zoran

09 1900

Chez l’humain, différents protocoles de stimulation magnétique transcrânienne répétée (SMTr) peuvent être utilisés afin de manipuler expérimentalement la plasticité cérébrale au niveau du cortex moteur primaire (M1). Ces techniques ont permis de mieux comprendre le rôle du sommeil dans la régulation de la plasticité cérébrale. Récemment, une étude a montré que lorsqu’une première session de stimulation SMTr au niveau de M1 est suivie d’une nuit de sommeil, l’induction subséquente de la plasticité par une deuxième session SMTr est augmentée. La présente étude a investigué si ce type de métaplasticité pouvait également bénéficier d’une sieste diurne. Quatorze sujets en santé ont reçu deux sessions de intermittent theta burst stimulation (iTBS) connue pour son effet facilitateur sur l’excitabilité corticale. Les sessions de stimulation étaient séparées par une sieste de 90 minutes ou par une période équivalente d’éveil. L’excitabilité corticale était quantifiée en terme d’amplitude des potentiels évoqués moteurs (PEM) mesurés avant et après chaque session de iTBS. Les résultats montrent que la iTBS n’est pas parvenue à augmenter de manière robuste l’amplitude des PEMs lors de la première session de stimulation. Lors de la deuxième session de stimulation, la iTBS a produit des changements plastiques variables et ce peu importe si les sujets ont dormi ou pas. Les effets de la iTBS sur l’excitabilité corticale étaient marqués par une importante variabilité inter et intra-individuelle dont les possibles causes sont discutées. / In humans, various repetitive transcranial magnetic stimulation (rTMS) protocols can be used to modulate motor cortical plasticity. These techniques have shed light on the role of sleep in neural plasticity regulation. Recent work has demonstrated that when a night of sleep follows one session of rTMS over the hand motor cortex (M1), the capacity to induce subsequent plasticity by another rTMS session in M1 is enhanced. The present study investigated whether such metaplasticity could also benefit from a day nap. Fourteen healthy participants received two sessions of intermittent theta burst stimulation (iTBS) known for its excitatory effects on cortical excitability over M1 spaced by either a 90-minute nap or an equivalent amount of wake. Motor cortical excitability was measured in terms of amplitude of motor evoked potentials (MEP), which were assessed before iTBS and after the stimulation. Results show that the first iTBS session did not induce significant change in MEP amplitude. The second iTBS session induced variable plastic changes regardless of whether participants slept or stayed awake. The effects of iTBS on motor cortical excitability were highly variable within and between individuals. The possible causes of such variability are discussed.

Plasticité cérébrale

Sommeil

Sieste

Theta burst stimulation (TBS)

Métaplasticité

Variabilité

Humain

Plasticity

Sleep

Nap

Transcranial magnetic stimulation (TMS)

Metaplasticity

Variability

Human

Development of instrumentation for neuronavigation and transcranial magnetic stimulation / Desenvolvimento de instrumentação para neuronavegação e estimulação magnética transcraniana

Souza, Victor Hugo de Oliveira e

23 February 2018

Neuronavigation and transcranial magnetic stimulation (TMS) are valuable tools in clinical and research environment. Neuronavigation provides visual guidance of a given instrument during procedures of neurological interventions, relative to anatomic images. In turn, TMS allows the non-invasive study of cortical brain function and to treat several neurological disorders. Despite the well-accepted importance of both techniques, high-cost of neuronavigation systems and limited spatial accuracy of TMS in targeting brain structures, limit their applications. Therefore, the aim of this thesis was to i) develop an open-source, free neuronavigation software, ii) study a possible combination of neuronavigation and 3D printing for surgical planning, and iii) construct a multi-channel TMS coil with electronic control of electric field (E-field) orientation. In the first part, we developed and characterized a neuronavigation software compatible with multiple spatial tracking devices, the InVesalius Navigator. The created co-registration algorithm enabled tracking position and orientation of instruments with an intuitive graphical interface. Measured accuracy was similar to that of commercial systems. In the second part, we created 3D printed models from patients with neurological disorders and assessed the errors of localizing anatomical landmarks during neuronavigation. Localization errors were below 3 mm, considered acceptable for clinical applications. Finally, in the last part, we combined a set of two thin, overlapping coils to allow electronic control of the E-field orientation and investigated how the motor evoked responses depend on the stimulus orientation. The developed coil enabled the stimulation of the motor cortex with high angular resolution. Motor responses showed the highest amplitude and lowest latency with E-field approximately perpendicular to the central sulcus. In summary, this thesis provides new methods to improve spatial accuracy of techniques to brain interventions. / A neuronavegação e a estimulação magnética transcraniana (EMT ou TMS, do termo em inglês transcranial magnetic stimulation) têm sido apresentadas como ferramentas valiosas em aplicações clínicas e de pesquisa. A neuronavegação possibilita a localização de instrumentos em relação a imagens anatômicas durante procedimentos de intervenção neurológica. Por sua vez, a EMT permite o estudo não invasivo da função cerebral e o tratamento de doenças neurológicas. Apesar da importância de ambas as técnicas, o alto custo dos sistemas de neuronavegação e a reduzida precisão espacial da EMT em ativar estruturas cerebrais limitam suas aplicações. Sendo assim, o objetivo desta tese foi: i) desenvolver um software de neuronavegação gratuito e de código aberto, ii) estudar a combinação entre neuronavegação e impressão 3D para planejamento cirúrgico, e iii) construir uma bobina de EMT multicanal com controle eletrônico da orientação do campo elétrico (CE). Na primeira parte, desenvolvemos e caracterizamos um software de neuronavegação compatível com vários rastreadores espaciais, o InVesalius Navigator. O algoritmo criado possibilitou o rastreamento de instrumentos por uma interface gráfica intuitiva. A precisão medida foi semelhante à de sistemas comerciais. Na segunda parte, imprimimos modelos 3D de pacientes com patologias neurológicas e avaliamos os erros de localização de marcos anatômicos durante a neuronavegação. Os erros de localização foram inferiores a 3 mm, considerados aceitáveis para aplicações clínicas. Por fim, na última parte, combinamos duas bobinas sobrepostas para controlar eletronicamente a orientação do CE, e investigamos como as respostas motoras evocadas dependem da orientação da corrente. A bobina desenvolvida possibilitou estimular o córtex motor com alta resolução angular. As respostas motoras apresentaram maior amplitude e menor latência para orientação do CE aproximadamente perpendicular ao sulco central. Em suma, esta tese fornece novos métodos para melhorar a precisão espacial de técnicas de intervenção com o cérebro.

3D printing

Coil orientation

Impressão 3D

Motor evoked potentials (MEP)

Neuronavegação

Neuronavigation

Orientação da bobina

Planejamento cirúrgico

Potencial evocado motor (PEM)

Surgical planning

Transcranial magnetic stimulation (TMS)

Steigerung der Effektivität repetitiver Doppelpuls-TMS mit I-Wellen-Periodizität (iTMS) durch individuelle Adaptation des Interpulsintervalls

Sewerin, Sebastian

01 December 2014

Die transkranielle Magnetstimulation (TMS) ist ein nichtinvasives Hirnstimulationsverfahren, mit welchem sowohl die funktionelle Untersuchung umschriebener kortikaler Regionen als auch die Modulation der Erregbarkeit ebendieser sowie die Induktion neuroplastischer Phänomene möglich ist. Sie wurde in der Vergangenheit insbesondere bei der Erforschung des humanen zentralmotorischen Systems angewandt. Dabei zeigte sich, dass ein einzelner über dem primärmotorischen Areal (M1) applizierter TMS-Puls multiple deszendierende Erregungswellen im Kortikospinaltrakt induzieren kann. Von diesen Undulationen besitzt die D-Welle (direkte Welle) die kürzeste Latenz und sie rekurriert auf eine direkte Aktivierung kortikospinaler Neurone, wohingegen I-Wellen (indirekte Wellen) längere Latenzen besitzen und durch transsynaptische Aktivierung dieser Zellen entstehen. Bemerkenswert ist das periodische Auftreten der letztgenannten Erregungswellen mit einer Periodendauer von etwa 1,5 ms. Zwar sind die genauen Mechanismen noch unbekannt, welche der Entstehung dieser I-Wellen sowie dem Phänomen der I-Wellen-Fazilitierung, das sich in geeigneten TMS-Doppelpulsprotokollen offenbart, zugrunde liegen, jedoch existieren hierzu verschiedene Erklärungsmodelle. Im Mittelpunkt der vorliegenden Arbeit steht die repetitive Anwendung eines TMS-Doppelpulsprotokolls, bei dem das Interpulsintervall (IPI) im Bereich der I-Wellen-Periodizität liegt (iTMS) und das gleichsam durch eine Implementierung der I-Wellen-Fazilitierung in der repetitiven TMS charakterisiert ist. Da gezeigt werden konnte, dass iTMS mit einem IPI von 1,5 ms (iTMS_1,5ms) die kortikospinale Erregbarkeit signifikant intra- und postinterventionell zu steigern vermag, und die I-Wellen-Periodizität interindividuellen Schwankungen unterliegt, wurde in der hier vorgestellten Studie an Normalprobanden der Einfluss einer individuellen Anpassung des IPIs (resultierend in der iTMS_adj) auf die intrainterventionelle kortikospinale Erregbarkeit untersucht. In der Tat stellte sich heraus, dass die iTMS_adj der iTMS_1,5ms diesbezüglich überlegen ist. Dieses Ergebnis unterstreicht das Potential einer Individualisierung der interventionellen TMS für erregbarkeitsmodulierende Effekte und macht dasjenige der ohnehin auf physiologische Prozesse abgestimmten iTMS explizit, was insbesondere für klinische Anwendungen relevant sein mag.

transkranielle Magnetstimulation (TMS)

I-Wellen-Periodizität

motorisch evoziertes Potential (MEP)

primärmotorischer Kortex (M1)

kortikospinale Erregbarkeit

Doppelpulsstimulation

transcranial magnetic stimulation (TMS)

I-wave periodicity

motor evoked potential (MEP)

primary motor cortex (M1)

corticospinal excitability

paired-pulse stimulation

ddc:612

Development of instrumentation for neuronavigation and transcranial magnetic stimulation / Desenvolvimento de instrumentação para neuronavegação e estimulação magnética transcraniana

Victor Hugo de Oliveira e Souza

23 February 2018

Neuronavigation and transcranial magnetic stimulation (TMS) are valuable tools in clinical and research environment. Neuronavigation provides visual guidance of a given instrument during procedures of neurological interventions, relative to anatomic images. In turn, TMS allows the non-invasive study of cortical brain function and to treat several neurological disorders. Despite the well-accepted importance of both techniques, high-cost of neuronavigation systems and limited spatial accuracy of TMS in targeting brain structures, limit their applications. Therefore, the aim of this thesis was to i) develop an open-source, free neuronavigation software, ii) study a possible combination of neuronavigation and 3D printing for surgical planning, and iii) construct a multi-channel TMS coil with electronic control of electric field (E-field) orientation. In the first part, we developed and characterized a neuronavigation software compatible with multiple spatial tracking devices, the InVesalius Navigator. The created co-registration algorithm enabled tracking position and orientation of instruments with an intuitive graphical interface. Measured accuracy was similar to that of commercial systems. In the second part, we created 3D printed models from patients with neurological disorders and assessed the errors of localizing anatomical landmarks during neuronavigation. Localization errors were below 3 mm, considered acceptable for clinical applications. Finally, in the last part, we combined a set of two thin, overlapping coils to allow electronic control of the E-field orientation and investigated how the motor evoked responses depend on the stimulus orientation. The developed coil enabled the stimulation of the motor cortex with high angular resolution. Motor responses showed the highest amplitude and lowest latency with E-field approximately perpendicular to the central sulcus. In summary, this thesis provides new methods to improve spatial accuracy of techniques to brain interventions. / A neuronavegação e a estimulação magnética transcraniana (EMT ou TMS, do termo em inglês transcranial magnetic stimulation) têm sido apresentadas como ferramentas valiosas em aplicações clínicas e de pesquisa. A neuronavegação possibilita a localização de instrumentos em relação a imagens anatômicas durante procedimentos de intervenção neurológica. Por sua vez, a EMT permite o estudo não invasivo da função cerebral e o tratamento de doenças neurológicas. Apesar da importância de ambas as técnicas, o alto custo dos sistemas de neuronavegação e a reduzida precisão espacial da EMT em ativar estruturas cerebrais limitam suas aplicações. Sendo assim, o objetivo desta tese foi: i) desenvolver um software de neuronavegação gratuito e de código aberto, ii) estudar a combinação entre neuronavegação e impressão 3D para planejamento cirúrgico, e iii) construir uma bobina de EMT multicanal com controle eletrônico da orientação do campo elétrico (CE). Na primeira parte, desenvolvemos e caracterizamos um software de neuronavegação compatível com vários rastreadores espaciais, o InVesalius Navigator. O algoritmo criado possibilitou o rastreamento de instrumentos por uma interface gráfica intuitiva. A precisão medida foi semelhante à de sistemas comerciais. Na segunda parte, imprimimos modelos 3D de pacientes com patologias neurológicas e avaliamos os erros de localização de marcos anatômicos durante a neuronavegação. Os erros de localização foram inferiores a 3 mm, considerados aceitáveis para aplicações clínicas. Por fim, na última parte, combinamos duas bobinas sobrepostas para controlar eletronicamente a orientação do CE, e investigamos como as respostas motoras evocadas dependem da orientação da corrente. A bobina desenvolvida possibilitou estimular o córtex motor com alta resolução angular. As respostas motoras apresentaram maior amplitude e menor latência para orientação do CE aproximadamente perpendicular ao sulco central. Em suma, esta tese fornece novos métodos para melhorar a precisão espacial de técnicas de intervenção com o cérebro.

Impressão 3D

Neuronavegação

Orientação da bobina

Planejamento cirúrgico

Potencial evocado motor (PEM)

3D printing

Coil orientation

Motor evoked potentials (MEP)

Neuronavigation

Surgical planning

Transcranial magnetic stimulation (TMS)

The role of pulse shape in motor cortex transcranial magnetic stimulation using full-sine stimuli

Delvendahl, Igor, Gattinger, Norbert, Berger, Thomas, Gleich, Bernhard, Siebner, Hartwig R., Mall, Volker

January 2014

A full-sine (biphasic) pulse waveform is most commonly used for repetitive transcranial magnetic stimulation (TMS), but little is known about how variations in duration or amplitude of distinct pulse segments influence the effectiveness of a single TMS pulse to elicit a corticomotor response. Using a novel TMS device, we systematically varied the configuration of full-sine pulses to assess the impact of configuration changes on resting motor threshold (RMT) as measure of stimulation effectiveness with single-pulse TMS of the non-dominant motor hand area (M1). In young healthy volunteers, we (i) compared monophasic, half-sine, and full-sine pulses, (ii) applied two-segment pulses consisting of two identical half-sines, and (iii) manipulated amplitude, duration, and current direction of the first or second full-sine pulse half-segments. RMT was significantly higher using half-sine or monophasic pulses compared with full-sine. Pulses combining two half-sines of identical polarity and duration were also characterized by higher RMT than fullsine stimuli resulting. For full-sine stimuli, decreasing the amplitude of the halfsegment inducing posterior-anterior oriented current in M1 resulted in considerably higher RMT, whereas varying the amplitude of the half-segment inducing anterior-posterior current had a smaller effect. These findings provide direct experimental evidence that the pulse segment inducing a posterior anterior directed current in M1 contributes most to corticospinal pathway excitation. Preferential excitation of neuronal target cells in the posterior-anterior segment or targeting of different neuronal structures by the two half-segments can explain this result. Thus, our findings help understanding the mechanisms of neural stimulation by full-sine TMS.

info:eu-repo/classification/ddc/610

ddc:610

info:eu-repo/classification/ddc/537

ddc:537

Selektive Modulation des Erregbarkeitsniveaus am motorischen Cortex durch transkranielle Wechsel- und Rauschstrom-Stimulation mit unterschiedlichen Intensitäten / Selective modulation of the excitability level on the motor cortex by transcranial AC and noise current stimulation with different intensities

Atalay, Deniz-Arman

02 July 2020

No description available.

610

nicht-invasive Hirnstimulation

transkranielle Magnetstimulation (TMS)

Neuroplastizität

kortikale Erregbarkeit

non-invasive brain stimulation

transcranial magnetic stimulation (TMS)

neuroplasticity

cortical excitability

Steigerung der Effektivität repetitiver Doppelpuls-TMS mit I-Wellen-Periodizität (iTMS) durch individuelle Adaptation des Interpulsintervalls

Sewerin, Sebastian

01 November 2012

Die transkranielle Magnetstimulation (TMS) ist ein nichtinvasives Hirnstimulationsverfahren, mit welchem sowohl die funktionelle Untersuchung umschriebener kortikaler Regionen als auch die Modulation der Erregbarkeit ebendieser sowie die Induktion neuroplastischer Phänomene möglich ist. Sie wurde in der Vergangenheit insbesondere bei der Erforschung des humanen zentralmotorischen Systems angewandt. Dabei zeigte sich, dass ein einzelner über dem primärmotorischen Areal (M1) applizierter TMS-Puls multiple deszendierende Erregungswellen im Kortikospinaltrakt induzieren kann. Von diesen Undulationen besitzt die D-Welle (direkte Welle) die kürzeste Latenz und sie rekurriert auf eine direkte Aktivierung kortikospinaler Neurone, wohingegen I-Wellen (indirekte Wellen) längere Latenzen besitzen und durch transsynaptische Aktivierung dieser Zellen entstehen. Bemerkenswert ist das periodische Auftreten der letztgenannten Erregungswellen mit einer Periodendauer von etwa 1,5 ms. Zwar sind die genauen Mechanismen noch unbekannt, welche der Entstehung dieser I-Wellen sowie dem Phänomen der I-Wellen-Fazilitierung, das sich in geeigneten TMS-Doppelpulsprotokollen offenbart, zugrunde liegen, jedoch existieren hierzu verschiedene Erklärungsmodelle. Im Mittelpunkt der vorliegenden Arbeit steht die repetitive Anwendung eines TMS-Doppelpulsprotokolls, bei dem das Interpulsintervall (IPI) im Bereich der I-Wellen-Periodizität liegt (iTMS) und das gleichsam durch eine Implementierung der I-Wellen-Fazilitierung in der repetitiven TMS charakterisiert ist. Da gezeigt werden konnte, dass iTMS mit einem IPI von 1,5 ms (iTMS_1,5ms) die kortikospinale Erregbarkeit signifikant intra- und postinterventionell zu steigern vermag, und die I-Wellen-Periodizität interindividuellen Schwankungen unterliegt, wurde in der hier vorgestellten Studie an Normalprobanden der Einfluss einer individuellen Anpassung des IPIs (resultierend in der iTMS_adj) auf die intrainterventionelle kortikospinale Erregbarkeit untersucht. In der Tat stellte sich heraus, dass die iTMS_adj der iTMS_1,5ms diesbezüglich überlegen ist. Dieses Ergebnis unterstreicht das Potential einer Individualisierung der interventionellen TMS für erregbarkeitsmodulierende Effekte und macht dasjenige der ohnehin auf physiologische Prozesse abgestimmten iTMS explizit, was insbesondere für klinische Anwendungen relevant sein mag.

info:eu-repo/classification/ddc/612

ddc:612