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Long Latency Reflexes in Clinical Neurology: A Systematic Review

Published online by Cambridge University Press:  08 July 2022

Debjyoti Dhar
Affiliation:
Department of Neurology, National Institute of Mental Health & Neuro Sciences (NIMHANS), Hosur Road, Bangalore 560029, Karnataka, India
Nitish Kamble
Affiliation:
Department of Neurology, National Institute of Mental Health & Neuro Sciences (NIMHANS), Hosur Road, Bangalore 560029, Karnataka, India
Pramod Kumar Pal*
Affiliation:
Department of Neurology, National Institute of Mental Health & Neuro Sciences (NIMHANS), Hosur Road, Bangalore 560029, Karnataka, India
*
Corresponding author: Dr. Pramod Kumar Pal, Professor, Department of Neurology, National Institute of Mental Health & Neurosciences (NIMHANS), Bangalore-560029, India. Email: [email protected]
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Abstract:

Background:

Long latency reflexes (LLRs) are impaired in a wide array of clinical conditions. We aimed to illustrate the clinical applications and recent advances of LLR in various neurological disorders from a systematic review of published literature.

Methods:

We reviewed the literature using appropriately chosen MeSH terms on the database platforms of MEDLINE, Web of Sciences, and Google Scholar for all the articles from 1st January 1975 to 2nd February 2021 using the search terms “long loop reflex”, “long latency reflex” and “C-reflex”. The included articles were analyzed and reported using synthesis without meta-analysis (SWiM) guidelines.

Results:

Based on our selection criteria, 40 articles were selected for the systematic review. The various diseases included parkinsonian syndromes (11 studies, 217 patients), Huntington’s disease (10 studies, 209 patients), myoclonus of varied etiologies (13 studies, 127 patients) including progressive myoclonic epilepsy (5 studies, 63 patients) and multiple sclerosis (6 studies, 200 patients). Patients with parkinsonian syndromes showed large amplitude LLR II response. Enlarged LLR II was also found in myoclonus of various etiologies. LLR II response was delayed or absent in Huntington’s disease. Delayed LLR II response was present in multiple sclerosis. Among the other diseases, LLR response varied according to the location of cerebellar lesions while the results were equivocal in patients with essential tremor.

Conclusions:

Abnormal LLR is observed in many neurological disorders. However, larger systematic studies are required in many neurological disorders in order to establish its role in diagnosis and management.

Résumé :

RÉSUMÉ :

Les réflexes de longue latence en neurologie clinique : résultats d’une synthèse systématique.

Contexte :

Les réflexes de longue latence (RLL) sont perturbés dans bon nombre d’états cliniques. L’étude visait à dégager, d’une synthèse systématique de la documentation médicale publiée, les applications cliniques de l’analyse des RLL dans divers troubles neurologiques et les progrès récents réalisés en la matière.

Méthode :

Il s’agit d’un examen de la documentation effectué à l’aide, tout d’abord, d’expressions MeSH bien choisies dans les bases de données MEDLINE, Web of Sciences et Google Scholar, provenant de tous les articles publiés du 1er janvier 1975 au 2 février 2021, puis des termes de recherche suivants : long loop reflex, long latency reflex et Creflex. Les articles retenus ont fait l’objet d’analyse et ensuite de déclaration selon les lignes directrices sur les synthèses sans méta-analyse (SWiM).

Résultats :

D’après les critères de sélection, 40 articles ont été retenus en vue de la synthèse systématique. Les différentes affections comprenaient les syndromes parkinsoniens (11 études; 217 patients), la chorée de Huntington (10 études; 209 patients), la myoclonie d’origine diverse (13 études; 127 patients), y compris l’épilepsie myoclonique progressive (5 études; 63 patients) et la sclérose en plaques (6 études; 200 patients). Des RLL de type II de grande amplitude ont été observés dans les syndromes parkinsoniens, de même que dans la myoclonie de différentes causes. Par contre, il y avait retard ou absence de RLL de type II dans la chorée de Huntington, et retard dans la sclérose en plaques. Parmi les autres affections, les RLL variaient selon le siège des lésions cérébelleuses, et donnaient des résultats ambigus chez les patients atteints du tremblement essentiel.

Conclusion :

Des RLL anormaux ont été observés dans divers troubles neurologiques. Toutefois, il faudrait réaliser des synthèses systématiques de plus grande taille portant sur de nombreuses affections neurologiques afin d’établir leur rôle dans le diagnostic et la prise en charge.

Type
Original Article
Copyright
© The Author(s), 2022. Published by Cambridge University Press on behalf of Canadian Neurological Sciences Federation

Introduction

The origin of stretch reflex holds its roots way back to 1924 when it was first tested in the decerebrate cats after sectioning at inter-collicular level, then termed as “tonic reflex”.Reference Liddell and Sherrington1 Further animal experiments attributed the origin of stretch reflex to the spinal level.Reference Denny-Brown2 Three decades later, Hammond et al. demonstrated the existence of two components in response to stretch reflex during voluntary contraction of a muscle.Reference Hammond3,Reference Hammond4 The early response with shorter latency, representing the mono-synaptic pathway was called M1 and the later ones were called M2 and M3 responses.Reference Tatton, Forner, Gerstein, Chambers and Liu5 Although the role of transcortical pathways in mediating long latency responses was first proposed by Philips, it was Marsden, Merton, and Morton who substantiated it.Reference Phillips6,Reference Marsden, Merton and Morton7,Reference Marsden, Merton and Morton8,Reference Marsden, Merton and Morton9 Deuschl et al. through their series of papers on long latency reflex (LLR) contributed enormously to the further understanding of the concepts.Reference Deuschl, Schenck and Lücking10 They put forward the subtypes of LLR into I, II, and III that forms the basis of research and applications. Since then, the principles have been applied, albeit with modifications and added modalities of electrophysiology, on a plethora of clinical conditions spanning across the entire spectrum of neurological sciences and beyond.

Deuschl et al. defined LLR, as “involuntary muscle responses which succeed the short latency response and precede the voluntary response, irrespective of whether the stimulus is muscle stretch, electrical stimulation of a nerve or a more complex stimulus”.Reference Deuschl and Lücking11 The wide spectrum of abnormalities exhibited by these reflexes in various clinical conditions render it as one of the promising tools in clinical neurophysiology not only as an ancillary aid in the diagnosis but also in, prognostication, following the progress of disease and depicting the neural circuitry involved in their pathophysiology. Following the detailed review article on the various clinical applications of hand muscle reflexes by Deuschl and Lucking in 1990, there has been no further consolidation on this topic even though the spectrum of applications of LLR has expanded manifold through a vast number of research papers.Reference Deuschl and Lücking11 Therefore, a systematic review encompassing the old, the new, and the emerging concepts with its applications across the fields of neuroscience was felt as the need of the hour.

The Technical Aspects of LLR and Nomenclature

The technique to elicit LLR has been subjected to considerable modifications time and again by various authors. However, the most commonly used method in the majority of the studies testing hand muscle reflexes is in accordance with the procedure outlined by Deuschl et al.Reference Deuschl, Schenck and Lücking10,Reference Deuschl and Lücking11 The method involves electrical stimulation of the median nerve at the wrist, with the thumb, kept abducted at 15–20% of maximal force. Surface EMG recording is obtained from abductor pollicis brevis, filtered at 10–3000 Hz, rectified, and averaged over 64–256 sweeps. The methodology described by Conrad and Aschoff, a few years earlier was on similar lines with some minor modifications.Reference Conrad and Aschoff12 Lefaucheur et al. criticized the procedure of using 20% of the maximal force while recording LLR among patients with Huntington’s disease (HD). In their study on electrophysiological assessment in HD, they instructed the patients to exert near-maximal effort, following which they could demonstrate the presence of LLR, contrary to the previous studies on HD.Reference Lefaucheur, Bachoud-Levi and Bourdet13 Among the other modifications, in a study on idiopathic scoliosis, LLR was recorded intra-operatively by stimulating posterior tibial and common peroneal nerve while surface EMG was recorded from vastus medialis, tibialis anterior, gastrocnemius, and abductor hallucis.Reference Maguire, Madigan, Wallace, Draper and Leppanen14 LLR has also been recorded from superficial trunk muscles (rectus abdominis and erector spinae) in a study on chronic low back pain.Reference Shenoy, Balachander and Sandhu15 Besides, LLR of lower limbs has also been used as a part of static and dynamic posturography while testing for vestibulo-oculo-reflex using stabilometric platforms, the methodology of which has been described in various studies.Reference Diener, Dichgans, Bootz and Bacher16,Reference Dellepiane, Medicina, Mora and Salami17

Pattern of Reflexes and Terminologies

Reflexes on muscle stretch: The reflex patterns and terminologies depend on the method of stimulation. In response to muscle stretch, the first response is referred to as M1, which represents monosynaptic transmission by group IA afferents. This is followed by M2 response, mediated by trans-cortical pathways.Reference Deuschl and Lücking11 The M2 response from proximal upper limb is conducted by group II afferents and involves the spinal pathways.Reference Deuschl and Lücking11 The M3 response, which follows M2, represents a modulation of reflex pathways by cerebellum, the details of which are still not well delineated.Reference Deuschl and Lücking11 In the lower limbs, the reflexes are less well defined compared to that of hand reflexes. A distinct medium latency reflex (MLR) has been reported in 50% of normal subjects, occurring at 110–120 ms from stimulation, generated by the stretched agonist muscle and has been thought to be mediated by transcortical pathways.Reference Diener, Dichgans, Bootz and Bacher16 The generation of LLR in the lower limbs is related to stabilization of posture when the body is subjected to sudden displacement. It is the antagonist of a stretched muscle which generates LLR and thereby aids in stabilization of posture. Such a response is absent when the muscle is stretched in supine or sitting position.Reference Diener, Dichgans, Bootz and Bacher16

Reflexes on Electrical Stimulation: On electrical stimulation of a mixed nerve in the hand, the first reflex obtained at a mean latency of 29 ms is called short latency reflex (SLR), which represents stimulation of group IA afferents mediating a monosynaptic reflex.Reference Conrad and Aschoff12,Reference Deuschl and Lücking11 The nomenclature of the LLR stands as LLR I, LLR II, and LLR III occurring at mean latencies of 40, 50, and 75 ms, respectively.Reference Deuschl and Lücking11 In this system, LLR I represent the early excitatory component, while LLR II, the most consistent one, is mediated by transcortical loop akin to the M2 response on stretch reflex. Finally, LLR III, representing the late excitatory response, is inconsistently seen among healthy subjects.

The cutaneous stimulation of digital nerves or superficial radial nerve leads to early excitatory (E1) also referred to cLLR I (cutaneous long latency reflex), early inhibitory (I1), and late excitatory (E2), also known as cLLR II responses.Reference Jenner and Stephens20 Comparing the various modes of stimulation, it is most likely that HR and SLR represents M1, LLR II is equivalent to E2 and M2 response, and LLR III is the equivalent of M3 response.Reference Deuschl and Lücking11,Reference Tatton and Lee18,Reference Deuschl and Eisen19 Enhanced LLR I response in the setting of cortical myoclonus is also referred to as C-reflex since its latency correlates with that of LLR I response.Reference Deuschl and Eisen19 The possible LLR transduction pathways with terminologies is depicted in Figure 1.

Figure 1: Long Latency reflex (LLR) transduction pathway and the levels involved in various clinical conditions. 1: Parkinson’s disease (PD), 1A: Abnormal Basal ganglia output leading to impaired modulation of transcortical pathways, 1B: Increased transmission by Group II afferents in PD, 1C: Altered excitability of spinal interneurons, 2: Cortical excitability in myoclonus, 3: Huntington’s disease (HD), reduced impulse transmission to the cortex at the thalamic or thalamocortical projection level 3A: Degeneration of neurons at Thalamus in HD, 3B: Degeneration of neurons in the cortico-cortical pathways in HD, 4: Impaired transmission of impulses along the ascending and descending fibres due to demyelinating plaques in Multiple Sclerosis. The figure was created with BioRender.com.

Methods

Search Strategy

We searched the database platforms of MEDLINE, Web of Sciences, and Google scholar using the Medical Subject Heading terms (MeSH) “long loop reflex”, “long latency reflex”, and “C-reflex”, for all the articles from 1st January 1975 till 2nd February 2021. The search strategy was modified in the Google Scholar search engine using additional search terms “clinical applications”, “disease”, or “disorder” in order to encompass the relevant studies.

Study Selection and Data Extraction

The studies were reviewed critically with respect to title, authors, type, and sample size by thorough screening of the abstracts. Duplicate articles were identified during the same process. Articles lacking abstracts were assessed based on the title. Subsequently, the articles were segregated based on inclusion and exclusion criteria. Studies having patient data and those based on applications of LLR on clinical entities were included for review. Exclusion criteria were applied to the studies which were 1) purely focused on physiological aspects, 2) animal-based, 3) non-English language, 4) viewpoints and perspectives, 5) lacking patient data, 7) case reports on a single patient, 8) diseases with less than four research papers on applications of LLR, and 9) review articles. A manual search of the reference lists of the selected studies was performed to avoid missing key articles. Critical analyses of the included studies were performed after full-text reading. Quality assessment of the included studies was done using QUADAS-2 scale for primary diagnostic accuracy studies.Reference Whiting, Weswood, Rutjes, Reitsma, Bossuyt and Kleijnen21 Subsequently, data extraction was performed from each of the articles with respect to the sample size, the disease in question, the technical details of the methodology followed, results of the studies, and the hypothesized pathophysiology. The synthesized data were reported as per the Synthesis Without Meta-analysis (SWiM) guidelines in Systematic reviews.Reference Campbell, McKenzie and Sowden22

Quality assessment: QUADAS-2 analyses showed all the included studies being “at risk of bias” since at least one of the items among the domains of “patient selection”, “index test”, “reference standard”, and “flow and timings” were found to be at high risk. This was largely attributable to the lack of randomization, case-control design, and dearth of the prior knowledge of diagnosis from reference standard before the performance of the index test. With regards to the assessment of concern for applicability, all except three studies had “low concern regarding applicability” based on the domains of patient selection, index test, and reference standard.

Results

Our search strategy yielded a total of 1828 studies, out of which, 114 duplicated articles were excluded prior to abstract screening. Inclusion and exclusion criteria were applied to the 1714 abstracts, following which 29 articles were considered eligible for full-text reading. Further 11 articles were added from the manual search of the reference lists. Subsequently, a total of 40 studies were considered for the final systematic review (Figure 2). This systematic review was not pre-registered.

Figure 2: Search strategy and study selection in accordance with Systematic review without meta-analysis (SWiM) guidelines.

Applications in Movement Disorders

LLR in Parkinsonian Syndromes (n = 11 Studies)

One of the earliest diseases where LLR was studied was Parkinson’s disease (PD). Of the 11 studies included on parkinsonian syndromes, the majority of the studies were on PD. The foundation was laid by Tatton and Lee in 1975, who for the first time analyzed the reflex responses to wrist flexion-extension movements in rigidity predominant parkinsonian patients.Reference Tatton and Lee18 They demonstrated a significant increase in response at the M2-M3 interval which was statistically significant compared to the controls. The minimally increased M1 response in the parkinsonian group was consistent with the clinical correlate of normal tendon reflex in this condition. The study by Hunter et al. on reflex pathways in parkinsonian patients revealed exaggerated LLR at a mean latency of 61.3 ± 5.1 ms suggestive of enhanced LLR II. Lack of LLR on stimulation of cutaneous afferents near fibular nerve, suggested the origin to be the fast-conducting non-cutaneous group I afferents.Reference Hunter, Ashby and Lang23 Rothwell et al. hypothesized that the parkinsonian rigidity stems from the quantitative alterations in the long loop pathways.Reference Rothwell, Obeso, Traub and Marsden24 A similar observation of enhanced LLR was also found by other researchers (Table 1).Reference Mortimer and Webster25,Reference Berardelli, Sabra and Hallett26,Reference Cody, Macdermott, Matthews and Richardson27

Table 1: Studies of LLR in Parkinsonian disorders

FPL: Flexor pollicis longus; LLR: Long latency reflex; MLR: medium latency reflex; PD: Parkinson’s disease; PPND: Pallido-ponto-nigral degeneration; SLR: short latency reflex; TB: Triceps brachii.

Role of MLR, LLR in “Off state” and Other Controversies. Studies of stretch reflexes in lower limbs of parkinsonian patients, demonstrated exaggeration of MLR, instead of LLR.Reference Scholz, Diener, Noth, Friedemann, Dichgans and Bacher28,Reference Bloem, Beckley, van Dijk, Zwinderman and Roos29 The study by Bloem et al. stands out from the previous studies concerning the methodology as they tested reflexes among PD patients in 12 hours “off” state. Their results did not attribute any significant early diagnostic value to these parameters, as altered reflex responses (MLR) was noted only among advanced long-standing PD patients.Reference Bloem, Beckley, van Dijk, Zwinderman and Roos29 The study effectively sheds light on the supraspinal dopaminergic control of LLR, which is the pathomechanism behind low LLR response in the off state. Besides, it also showed the poor diagnostic sensitivity of LLR in detecting early PD. In another study, SLR was found to be absent to both mechanical and electrical stimuli and LLR was detected to be of normal parameters.Reference Noth, Schürmann, Podoll and Schwarz30 While the former was hypothesized to be a result of altered fusimotor drive in PD patients, the latter was postulated to be due to the dependence of these reflexes on the degree of muscle length perturbations applied.Reference Noth, Schürmann, Podoll and Schwarz30 The experimental study by Fuhr et al. revealed a less pronounced first inhibitory component (I1) of the cutaneous reflex (CR) attributed to the loss of spinal inhibition in PD patients.Reference Fuhr, Zeffiro and Hallett31 In a single study on Ponto-pallido-nigral degeneration (PPND), Wszolek et al. showed the absence of LLR in a family of nine patients associated with chromosome 17q21-24, suggesting lack of cortical hyperexcitability.Reference Wszolek, Lagerlund, Steg and McManis32

LLR in Myoclonus (n = 13 Studies)

Myoclonus has been subjected to numerous levels of classifications based on clinical aspects, anatomical location, electrophysiological patterns, including transcranial magnetic stimulation (TMS), somatosensory evoked potentials (SEP), and LLR.Reference Shibasaki33,Reference Kojovic, Cordivari and Bhatia34,Reference Tassinari, Rubboli and Shibasaki35 Enhanced LLR I is most commonly observed followed by LLR III and rarely LLR II.Reference Cruccu and Deuschl36 One of the earliest studies on detailed electrophysiology in a patient of focal reflex myoclonus was carried out by Sutton and Mayer, where they demonstrated exaggerated LLR at a mean latency of 51 ms suggestive of LLR II, generated by the sensorimotor cortex, also called C-reflex (cortical reflex).Reference Sutton and Mayer37 Based on etiology, myoclonus may be physiological, essential with or without dystonia, epileptic, and symptomatic or secondary.Reference Kojovic, Cordivari and Bhatia34 Of the 13 included studies on myoclonus, 5 were on symptomatic myoclonus, where myoclonus was a part of another disease, 3 on essential myoclonus comprising the hereditary etiologies, and 5 were on progressive myoclonic epilepsy syndromes (Table 2).

Table 2: Studies of LLR in myoclonus

BAFME: Benign adult familial myoclonic epilepsy; CBD: cortico-basal degeneration; LBD: Lafora body disease; LLR: long latency reflex; MD: myoclonus-dystonia; MLR: medium latency reflex; SEP: somatosensory evoked potential; SLR: short latency reflex; ULD: Unverricht-Lundborg disease.

Symptomatic Myoclonus

Myoclonus in Corticobasal Degeneration (CBD): Monza et al. evaluated 10 patients with CBD, out of which 6 had myoclonus.Reference Monza, Ciano and Scaioli38 All of them had enhanced LLR with a lower SLR/LLR amplitude ratio compared to the controls. The mean latencies of these enhanced LLR corresponds to LLR I subtype. Similar results were obtained by Carella et al. in a study on 5 CBD patients with myoclonus, probably a reflection of enhanced cortical excitability.Reference Carella, Ciano, Panzica and Scaioli39 Thus, neurophysiological studies can serve as ancillary tests in the diagnosis of CBD with myoclonus.

Multiple System Atrophy (MSA) with Myoclonus : Okuma et al. studied consecutive patients with MSA, which included both the subtypes, of which 12 MSA-P (parkinsonian type) and 3 MSA-C (cerebellar type) had myoclonus. An enlarged LLR I (C-reflex) with a mean latency of 40 ms was observed in 7 patients, of which 6 were MSA-P variant.Reference Okuma, Fujishima, Miwa, Mori and Mizuno40

Myoclonus in PD : Caviness et al. performed electrophysiological analyses of the wrist and finger myoclonus in two patients with levodopa responsive PD. They did not observe any exaggerated LLR or giant SEP suggesting that they are unlikely to be cortical reflex myoclonus.Reference Caviness, Adler, Newman, Caselli and Muenter41 It was concluded that the origin of myoclonus was a byproduct of cortical pathology in PD manifesting as cortical myoclonus.Reference Hughes, Lees, Daniel and Blankson42

Orthostatic Myoclonus: This represents a variant, characterized by myoclonic jerks occurring predominantly on assuming upright posture.Reference Glass, Ahlskog and Matsumoto43 Gunduz et al. reported an electrophysiological profile of 7 patients with orthostatic myoclonus where they found the presence of C reflex (enhanced LLR I) in a single patient suggestive of the simultaneous presence of a degenerative condition resulting in myoclonus of cortical origin.Reference Gunduz, Tutuncu and Zeydan44

Cortical Myoclonus Associated with Rett Syndrome: Guerrini et al. studied 10 girls identified with Rett Syndrome, 9 of whom had demonstratable myoclonus. Exaggerated C-reflex with marked prolongation and the intracortical delay was detected in all of them.Reference Guerrini, Bonanni, Parmeggiani and Santucci45

Essential Myoclonus

Inherited Myoclonus-Dystonia syndrome: The electrophysiological features of inherited myoclonus-dystonia were evaluated by Li et al. in 6 patients, 3 of which were caused by a mutation in ϵ-sarcoglycan gene (SGCE) on chromosome 7q21, 2 belonging to DYT-11 family and one with undetermined etiology. There was no evidence of enhanced LLR amplitude or abnormal SEP, suggesting subcortical origin of myoclonus.Reference Li, Cunic and Paradiso46 Marelli et al., in their study on 9 patients of DYT-11 myoclonus-dystonia syndrome, found normal LLR, which corroborated with the findings of normal SEPs and TMS parameters. Thus, the results of both the studies were in clear agreement with each other.Reference Marelli, Canafoglia and Zibordi47

Epileptic Myoclonus

LLR in PME Syndromes

Unverricht–Lundborg Disease (ULD) and Lafora Body Disease (LBD ): Canafoglia et al. demonstrated consistently enlarged LLR in 8 ULD patients that correlated with enlarged P25 and N33 components of SEP.Reference Canafoglia, Ciano and Panzica48 The enlarged LLR in ULD is a single wave that is a mixture of LLR I and LLR II. LLR enlargement was less consistent in patients with LBD. However, they had enlarged mid-latency N60 component of SEP, attributable to the sustained and complex cortical circuitry. Facilitated LLR was also reported in a series of 25 patients with ULD.Reference Visani, Canafoglia and Sebastiano49 LLR subtype couldn't be delineated in these cases due to lack of data.Reference Visani, Canafoglia and Sebastiano49

Sialidosis: Canafoglia et al. showed multiphasic complex waveforms (2–3 components) in 3 patients with sialidosis compared to 10 ULD patients suggesting the presence of reverberating loops involving the motor cortex and subcortical-cerebellar connections.Reference Canafoglia, Franceschetti and Uziel50 The enhanced LLR corresponds to LLR II.

Benign Adult Familial Myoclonic Epilepsy (BAFME): Demura et al. evaluated a single family of BAFME, of which three patients had SAMD 12 gene mutation, one of which was found to have C-reflex (correlate of LLR in myoclonus) at 77 ms latency of onset (LLR III).Reference Demura, Demura, Ota, Kondo and Kinoshita51 It corroborated with giant flash visual evoked potential (VEP). The longer latency of the C-reflex obtained in these patients could be attributed to the technique used in this study. Contrary to the usual electrical test of LLR, the C-reflex was obtained using F-wave study from abductor hallucis muscle. Since the stimulation intensity used in F-wave tests is higher than that of electrical LLR test, the response might be induced from all types of afferent nerves, but not Ia/II only. Enhanced LLR I, enlarged SEP and positive spikes preceding myoclonus on jerk locked back averaging (JLBA) has been described in three patients with BAFME.Reference Manabe, Narai and Warita52

LLR in Huntington’s Disease (n = 10 Studies)

Noth et al. did not observe LLR in majority of the patients with HD which corroborated with reduced early cortical components of SEP amplitude.Reference Noth, Friedemann, Podoll and Lange53 Other studies by Thompson et al., and Noth et al. on 17 and 50 HD patients demonstrated similar results.Reference Thompson, Berardelli and Rothwell54,Reference Noth, Podoll and Friedemann55 Eisen et al. demonstrated absent R2 (equivalent to LLR) in majority of HD patients and half of at-risk subjects.Reference Eisen, Bohlega and Hayden56 In 1989, a study on 23 patients of HD by Deuschl et al., provided valuable insights as it concluded loss of LLR as fairly specific in HD. They showed lack of utility of LLR in detecting carriers of HD.Reference Deuschl, Lucking and Schenck57 Lefaucheur et al. studied 36 patients with adult-onset HD using various neurophysiologic measures. While the role of SEP was quite apparent as a sensitive marker of disease, LLR did not correlate with disease stage or duration.Reference Lefaucheur, Bachoud-Levi and Bourdet13 Two years follow up study of 20 patients with HD, LLR correlated with an increase in unified Huntington disease rating scale (UHDRS) motor score.Reference Lefaucheur, Menard-Lefaucheur and Maison58 Sebastiano et al. described three patients with HD, who had enhanced LLRs suggestive of a reverberant circuit involving motor cortex.Reference Rossi Sebastiano, Soliveri and Panzica59 Delayed LLR latency and prolonged duration were described in 27 HD patients by Huttunen et al. (Table 3).Reference Huttunen and Homberg60

Table 3: Studies of LLR in Huntington’s disease

HD: Huntington’s disease; HR: H-reflex; LLR: Long latency reflex; MLR: medium latency reflex; SLR: short latency reflex.

LLR in Other Movement Disorders

LLR in Tremor Disorders (n = 2 Studies): In a study on 45 subjects with essential tremor (ET) by Deuschl G et al., two distinct subgroups were identified.Reference Deuschl, Lvjcking and Schenckt61 One group had normal LLR (tremor frequency 5.5 to 10 Hz) while the other had enhanced LLR I (tremor frequency 5.5 to 10 Hz). The response to propranolol varied among the subgroups, with better responses in the former group. Elble et al., didn't find any correlation between frequency of tremor and latencies of stretch reflex.Reference Elble, Higgins and Moody62 Limited by the number of studies as well as sample size, the utility of LLR in the evaluation of tremor remains to be determined.

LLR in Hyperekplexia (n = 2 Studies): Markand et al. performed electrophysiological evaluation of patients with familial startle disease and observed augmented C-reflex which suggests the role of cortical neuronal hyperexcitability as the basic pathophysiologic mechanism underlying hyperekplexia.Reference Markand63 The C-reflex were recorded in the F-wave study, with a latency range of 60 to 75 ms, corroborative of LLR II/III subtype. However, Brown et al. did not observe enhanced C-reflex in eight patients with hereditary and sporadic hyperekplexia despite enlarged SEP in one patient. The rostro-caudal recruitment of muscles to noise and facial taps hinted at brainstem origin of the startle response.Reference Brown, Rothwell, Thompson, Britton, Day and Marsden64 In a case report by Luiz et al, a prominent C-reflex at 78 msec (LLR III) was noted in a patient with hyperekplexia secondary to neonatal hypoxia.Reference Luiz, Gherpelli and Reis65

LLR in Miscellaneous Movement Disorders (n = 4 Studies): Koster et al. observed bilateral LLR response to ipsilateral stimulation in patients with persistent mirror movements (PMM).Reference Köster, Lauk and Timmer66 Matthews et al. reported a case of Klippel-Feil syndrome with mirror movements, in which contralateral first dorsal interossei (FDI) showed comparable M2 response on stimulation of ipsilateral FDI.Reference Matthews, Farmer and Ingramt67

Patients with writer’s cramps have LLR I more frequently with enhanced amplitude compared to the controls.Reference Srinivasulu, Lakshmi and Borgohain68 Lee et al. demonstrated delayed LLR II response along with delayed cortical relay time (CRT) suggestive of dysfunction in the sensorimotor pathways in SCA-6 patients.Reference Lee, Chen, Liao, Wu and Soong69

LLR Following Therapeutic Interventions: A study on 34 patients with idiopathic focal dystonia revealed enlarged LLR I component with diminished LLR II which is attributable to the inhibitory effect of supplementary motor area (SMA) seen in dystonic subjects. Following Botulinum toxin, there was a reduction in the amplitude of LLR II without change in waveform of the opposite side, thereby maintaining a reciprocal relationship with LLR I suggesting the toxins effect at the neuromuscular level rather than central level.Reference Naumann and Reiners70 LLR II alterations following botulinum toxin administration suggest that central motor patterns involved in focal dystonia can be modified by peripheral inputs.Reference Naumann and Reiners70 In a study that assessed LLR while using levetiracetam in the management of cortical myoclonus, there was no significant influence of levetiracetam on LLR I among patients with cortical myoclonus. However, 3/9 patients had a reduction in SEP following levetiracetam use.Reference Striano, Manganelli, Boccella, Perretti and Striano71

Applications in Multiple Sclerosis (MS) (n = 6 Studies)

Deuschl et al. studied 47 patients with probable and definite MS. Pathological LLR was found in 79 and 61% of confirmed and probable MS which was statistically significant when compared to SSEP.Reference Dueschl, Strahl, Schenck and Lücking72 In a study of 23 patients with acute phase MS, there was prolongation of LLR II latency, suggestive of impairment along the LLR pathway.Reference Bonfiglio, Rossi and Sartucci73 Abnormalities either in the afferent or efferent pathway can lead to altered LLR II latency, unlike SEP which is dependent only on the afferent system, that explains more frequent abnormality of LLR compared to SEP among MS patients. Many other studies also highlighted the intracortical delay as the principal factor behind the increased LLR latency among MS patients, the sensitivity of which exceeds that of SEP (Table 4).Reference Iovichich74,Reference Michels and Wessel75,Reference Matsumoto and Kaneshige76,Reference Toydemİr, Gökyİğİt, Seleker and Çelebİ77

Table 4: Studies of LLR in Multiple sclerosis

LLR: Long latency reflex; MLR: medium latency reflex; MS: Multiple sclerosis; SEP: somatosensory evoked potential; SLR: short latency reflex.

Applications in Miscellaneous Neurological and Non-neurological Conditions

LLR in Cerebellar Disorders (n = 2 Studies): Friedman et al. evaluated stretch induced LLR response in patients with cerebellar disorders. They revealed the presence of enlarged M2/M3 complex (LLR II/III) in disorders of cerebellar hemisphere, lower vermis and anterior lobe atrophy. On the contrary, diffuse cerebellar lesions didn't reveal any conclusive findings. In the Friedreich’s ataxia subgroup, patients had markedly delayed or absence of M2/M3 complex. Authors have mentioned the limitation of distinguishing M2 and M3 response separately in view of overlapping latencies. Abnormalities of M3 response points towards the role of trans-cerebellar loop in modulation of M3 component of LLR.Reference Friedemann, Noth, Diener and Bacher78 In a study of 41 subjects with cerebellar disease by Diener et al., the SLR and MLR elicited by stretching triceps surae and LLR in the antagonist muscle (tibialis anterior) were found to be normal in patients with lesions restricted to cerebellar hemispheres or vestibulocerebellum; suggesting that the exact timing of these reflexes is independent of the cerebellum. Three patients with Friedreich’s ataxia had delayed MLR probably attributable to the suprasegmental pathway, and markedly delayed M3 response.Reference Diener, Dichgans, Bacher and Guschlbauer79

LLR in Cortical Dementia (n = 1 Study): In a pilot study of patients with fronto-temporal dementia (FTD), LLR II response was not observed in comparison to patients with Alzheimer’s disease (AD), who had normal LLR II response.Reference Chandra, Isaac, Mane, Bharath and Nagaraju80

LLR in Brain Tumor (n = 1 Study): Stetkarova et al. reported a case series of 3 patients with brain tumor adjoining central sulcus. All had enhanced SEP and only one had exaggerated LLR. The latencies have not been mentioned in the article. The results are attributed to the increased cortical hyperexcitability or suppression of cortical inhibitory activity.Reference Stetkarova, Stejskal and Kofler81

LLR in Rasmussen Encephalitis (n = 1 Study): Gündüz et al. studied LLR in three patients with Rasmussen encephalitis, and found the presence of enhanced LLR in all cases. One of the patients had C- reflex at a latency of 55 ms, suggestive of LLR II response. For the rest of patients, the latencies were not mentioned in the paper. The findings were attributed to the involvement of cortical pathways in stimulus sensitive positive and negative myoclonus.Reference Gündüz, Kiziltan, Coşkun, Delil, Yeni and Özkara82

LLR in Adrenomyeloneuropathy (n = 1 Study): Liao et al. measured LLR and CRT in 2 patients with normal MRI and compared with 10 controls. They demonstrated delayed LLR with a latency that corresponds to LLR II.Reference Liao, Chen, Lin, Chen, Kao and Wu83

LLR in Myotonic Dystrophy Type 1 (DM1) (n = 1 Study): In a study of 24 patients with DM1, abnormalities in the muscle twitch properties such as reduced H-reflex depression with less robust LLR response was observed.Reference Shields, Petrie and Ba84

LLR in Stroke (n = 3 Studies) and Neurorehabilitation (n = 1 Study): Results of LLR assessment among long term stroke-survivors were contradictory.Reference Faig and Busse85,Reference Groenewegen, de Groot, Schouten, Maier, Arendzen and Meskers86,Reference Trumbower, Finley, Shemmell, Honeycutt and Perreault87 A more recent study by Bank C et al. showed that stroke survivors with intact LLR, have a better clinical recovery with respect to walking speed and power of ankle flexors compared to healthy controls. Patients who were LLR negative had dysfunctional modulation of stretch responses.Reference Banks, Little, Walker and Patten88 This highlights the potential role of LLR in the assessment of post-stroke recovery.

LLR in Idiopathic Scoliosis (n = 1 Study): Maguire et al. studied segmental reflex regulation in 37 patients with idiopathic scoliosis and 8 patients with secondary scoliosis, and demonstrated the presence of LLR in the idiopathic and their absence in the secondary group indicating the role of aberrant reflex pathways in the development of scoliosis.Reference Maguire, Madigan, Wallace, Draper and Leppanen14

LLR in Chronic Low Back Pain (n = 1 study): Shenoy et al. studied surface electromyograph of erector spinae and rectus abdominis muscles in athletes with chronic non-specific low backache (n = 25) and asymptomatic athletes (n = 24). They showed that symptomatic athletes had lower amplitude and delayed onset of LLR to unexpected perturbations, which is attributable to the task-modulated training of LLR which gets impaired in symptomatic athletes.Reference Shenoy, Balachander and Sandhu15

LLR and Theophyline (n = 1 Study): Bartel et al. studied the neurophysiological impact of theophylline on healthy volunteers. LLR showed no definite alterations from normal and no change following B6 supplementation. F wave latencies reduced and the percentage increased, highlighting the stimulatory effect of theophylline on neuraxis.Reference Bartel, Lotz, Delpori, Ubbink and Becker89

Discussion

The drive to understand the mechanism of rigidity in parkinsonian patients led to several LLR experiments, which advanced from animal models to human subjects and extended beyond, to the computational models.Reference Mashhadi Malek, Towhidkhah, Gharibzadeh, Daeichin and Ali Ahmadi-Pajouh90 The degeneration of neurons in the basal ganglia, as seen in PD has been thought to impair transmission via the thalamo-cortical structures to the motor cortex. Thus, the modulatory effect of basal ganglia prior to the voluntary movements is deemed to be affected in these patients, which subsequently leads to an exaggerated LLR response.Reference Tatton and Lee18 In the lower limbs, exaggerated MLR can be explained by the heightened excitability of the spinal reflex center due to the facilitatory inputs from group II afferents.Reference Cody, Macdermott, Matthews and Richardson27 Reduced first inhibitory component of cutaneous reflex has been accounted for by another plausible hypothesis which is based on the alteration of the excitability of spinal interneurons, that form the common converging site of cutaneous afferents and descending pyramidal fibers.Reference Fuhr, Zeffiro and Hallett31

The electrophysiology of HD revealed the absence of LLR as an important finding in this disorder. This, in presence of markedly diminished early cortical SEP with normal neck SEP, serves to reflect a crucial hypothesis that it is the diminished impulse transmission to the cortex at the thalamic or thalamocortical projection level, which is the most probable underlying pathophysiology.Reference Oepen, Doerr and Thoden91,Reference Noth, Engel, Friedemann and Lange92 This enables us to explain the trans-cortical loop-mediated delayed LLR II response. The behavioral alterations associated with HD could also be a manifest of the impaired transcortical loop.Reference Wiesendanger and Miles93 Besides, the greater diminution of LLR in distal joints compared to the wrist comes in line with the hypothesis of the greater output of transcortical pathways in the manipulation of distal small joints.Reference Thompson, Berardelli and Rothwell54,Reference Marsden, Rothwell and Day94 Conflicting results came from the study by Lefaucheur et al. attributable to the differences in the technical aspects of LLR measurement.Reference Lefaucheur, Bachoud-Levi and Bourdet13 A single study on the unique variant of HD also called the Westphal variant, had retained LLR.Reference Töpper, Schwarz, Lange, Hefter and Noth95

The studies on cortical myoclonus either sporadic, symptomatic, essential, or epileptic, revealed the presence of enhanced LLR, which when mediated by the sensorimotor cortex, is also called C-reflex.Reference Shibasaki33 However, LLR forms only a fraction of the armamentarium in the electrophysiological evaluation and classification of myoclonus.Reference Tassinari, Rubboli and Shibasaki35,Reference Park and Kim96 The studies on PME syndromes, a form of epileptic myoclonus, have reflected on the presence of cortical hyperexcitability which gets manifested in the form of enlarged LLR. One of the studies enlightened the difference in the occurrence of LLR enhancement between patients with ULD and sialodosis with greater prevalence in the former.Reference Canafoglia, Ciano and Panzica48

The studies on MS yielded consistent results with delayed LLR II response suggestive of slowing of impulse transmission in the central part of the reflex arc. In many of the other clinical entities studies are restricted to isolated case reports and small case series as mentioned above. LLR has also been assessed among patients undergoing botulinum toxin therapy for idiopathic focal dystonia, the effect of levodopa on cortical myoclonus, and CNS effects of theophylline therapy. There have been few studies on the applications of LLR outside the field of clinical neurosciences. Balestra C studied the role of LLR in the involuntary cessation of apnea.Reference Balestra, Levenez, Lafere, Dachy, Ezquer and Germonpre97 Oostveen et al. have studied LLR as a tool to detect delayed spinal cord ischemia during and after descending aorta repair.Reference Oostveen, Weerwind and Bergs98

Some of the novel areas where LLR has been studied to enlighten the neurophysiologic aspects or as a diagnostic marker were based on a small sample size. Large scale studies are still lacking in many of these clinical conditions, thereby rendering it difficult to draw meaningful conclusions or subject them to robust statistical analyses. Contrasting results from different studies on the same clinical entity based on differences in the measurement technique is an important aspect to consider before decision making. Some of the areas like properties of LLR in atypical parkinsonian syndromes and controlled studies on the role of dopaminergic medications on LLR have remained unexplored to a considerable extent.

Conclusions

Our systematic review provides valuable insights on the wide array of clinical applications of LLR particularly in the field of movement disorders. The disorders such as parkinsonian syndromes, Huntington’s disease and myoclonus of varied etiologies have been studied extensively till date which have yielded consistent results. Further research is needed to extend the applications of this electrophysiological tool in other areas of neurology.

Conflicts of Interest

None of the authors have any financial disclosures to make or have any conflict of interest.

Authors’ Roles

  1. 1. Debjyoti Dhar: Conceptualization, organization, execution, writing of first draft

  2. 2. Nitish Kamble: Conceptualization, organization, Manuscript review and critique

  3. 3. Pramod Kumar Pal: Conceptualization, supervision, organization, Manuscript review and critique

References

Liddell, EGT, Sherrington, CS. Reflexes in response to stretch (myotactic reflex). Proc R Soc Biol Sci. 1924;96:21242.Google Scholar
Denny-Brown, DE. The stretch reflex as a spinal process. J Physiol. 1927;63:144150.CrossRefGoogle ScholarPubMed
Hammond, PH. An experimental study of servo-action in human muscular control. Proc III Int Conf Med Electron. 1960, 1909.Google Scholar
Hammond, PH. The influence of prior instruction to the subject on an apparently involuntary neuro-muscular response. J Physiol. 1956;132:178.Google Scholar
Tatton, WG, Forner, SD, Gerstein, GL, Chambers, WW, Liu, CN. The effect of postcentral cortical lesions on motor responses to sudden upper limb displacements in monkeys. Brain Res. 1975;96:10813.CrossRefGoogle ScholarPubMed
Phillips, CG. The Ferrier Lecture, 1968 - Motor apparatus of the baboon’s hand. Proc R Soc London Ser B Biol Sci. 1968;173:14174, 1969.Google Scholar
Marsden, CD, Merton, PA, Morton, HB. Is the human stretch reflex cortical rather than spinal? Lancet. 1973;301:75961.CrossRefGoogle Scholar
Marsden, CD, Merton, PA, Morton, HB. Servo action in human voluntary movement. Nature. 1972;238:1403.CrossRefGoogle ScholarPubMed
Marsden, CD, Merton, PA, Morton, HB. Stretch reflex and servo action in a variety of human muscles. J Physiol. 1976;259:53160.CrossRefGoogle Scholar
Deuschl, G, Schenck, E, Lücking, CH. Long-latency responses in human thenar muscles mediated by fast conducting muscle and cutaneous afferents. Neurosci Lett. 1985;55:3616.CrossRefGoogle ScholarPubMed
Deuschl, G, Lücking, CH. Physiology and clinical applications of hand muscle reflexes. Electroencephalogr Clin Neurophysiol. 1990;41:84101.Google ScholarPubMed
Conrad, B, Aschoff, JC. Effects of voluntary isometric and isotonic activity on late transcortical reflex components in normal subjects and hemiparetic patients. Electroencephalogr Clin Neurophysiol. 1977;42:10716.CrossRefGoogle ScholarPubMed
Lefaucheur, JP, Bachoud-Levi, AC, Bourdet, C, et al. Clinical relevance of electrophysiological tests in the assessment of patients with Huntington’s disease. Mov Disord. 2002;17:1294301.CrossRefGoogle ScholarPubMed
Maguire, J, Madigan, R, Wallace, S, Draper, V, Leppanen, R. Intraoperative long-latency reflex activity in idiopathic scoliosis demonstrates abnormal central processing. A possible cause of idiopathic scoliosis. Spine. 1993;18:16216.CrossRefGoogle ScholarPubMed
Shenoy, S, Balachander, H, Sandhu, JS. Long latency reflex response of superficial trunk musculature in athletes with chronic low back pain. J Back Musculoskelet Rehabil. 2013;26:44550.Google ScholarPubMed
Diener, HC, Dichgans, J, Bootz, F, Bacher, M. Early stabilization of human posture after a sudden disturbance: influence of rate and amplitude of displacement. Exp Brain Res. 1984;56:12634.CrossRefGoogle ScholarPubMed
Dellepiane, M, Medicina, MC, Mora, R, Salami, A. Static and dynamic posturography in patients with asymptomatic HIV-1 infection and AIDS. Acta Otorhinolaryngol Ital. 2005;25:3538.Google ScholarPubMed
Tatton, WG, Lee, RG. Evidence for abnormal long-loop reflexes in rigid Parkinsonian patients. Brain Res. 1975;100:6716.CrossRefGoogle ScholarPubMed
Deuschl, G, Eisen, A. Long-latency reflexes following electrical nerve stimulation. Guidelines of the International Federation of Clinical Neurophysiology. EEG Suppl. 1999;52:2638.Google Scholar
Jenner, JR, Stephens, JA. Cutaneous reflex responses and their central nervous pathways studied in man. J Physiol. 1982;333:40519.CrossRefGoogle ScholarPubMed
Whiting, PF, Weswood, ME, Rutjes, AWS, Reitsma, JB, Bossuyt, PNM, Kleijnen, J. Evaluation of QUADAS, a tool for the quality assessment of diagnostic accuracy studies. BMC Med Res Methodol. 2006;6:25.CrossRefGoogle ScholarPubMed
Campbell, M, McKenzie, JE, Sowden, A, et al. Synthesis without meta-analysis (SWiM) in systematic reviews: reporting guideline. BMJ. 2020;368:16.Google ScholarPubMed
Hunter, JP, Ashby, P, Lang, AE. Afferents contributing to the exaggerated long latency reflex response to electrical stimulation in Parkinson’s disease. J Neurol Neurosurg Psychiatry. 1988;51:140510.CrossRefGoogle Scholar
Rothwell, JC, Obeso, JA, Traub, MM, Marsden, CD. The behaviour of the long-latency stretch reflex in patients with Parkinson’s disease. J Neurol Neurosurg Psychiatry. 1983;46:3544.CrossRefGoogle ScholarPubMed
Mortimer, JA, Webster, DD. Evidence for a quantitative association between EMG stretch responses and Parkinsonian rigidity. Brain Res. 1979;162:16973.CrossRefGoogle ScholarPubMed
Berardelli, A, Sabra, AF, Hallett, M. Physiological mechanisms of rigidity in Parkinson’s disease. J Neurol Neurosurg Psychiatry. 1983;46:4553.CrossRefGoogle ScholarPubMed
Cody, FWJ, Macdermott, N, Matthews, PBC, Richardson, HC. Observations on the genesis of the stretch reflex in Parkinson’s disease. Brain. 1986;109:22949.CrossRefGoogle ScholarPubMed
Scholz, E, Diener, HC, Noth, J, Friedemann, H, Dichgans, J, Bacher, M. Medium and long latency EMG responses in leg muscles: Parkinson’s disease. J Neurol Neurosurg Psychiatry. 1987;50:6670.CrossRefGoogle ScholarPubMed
Bloem, BR, Beckley, DJ, van Dijk, JG, Zwinderman, AH, Roos, RA. Are medium and long latency reflexes a screening tool for early Parkinson ’ s disease ? J Neurol Sci. 1992;3:3842.CrossRefGoogle Scholar
Noth, J, Schürmann, M, Podoll, K, Schwarz, M. Reconsideration of the concept of enhanced static fusimotor drive in rigidity in patients with Parkinson’s disease. Neurosci Lett. 1988;84:23943.CrossRefGoogle ScholarPubMed
Fuhr, P, Zeffiro, T, Hallett, M. Cutaneous reflexes in Parkinson;s disease. Muscle Nerve. 1992;15:7339.CrossRefGoogle ScholarPubMed
Wszolek, ZK, Lagerlund, TD, Steg, RE, McManis, PG. Clinical neurophysiologic findings in patients with rapidly progressive familial Parkinsonism and dementia with pallido-ponto-nigral degeneration. Electroencephalogr Clin Neurophysiol. 1998;107:21322.CrossRefGoogle ScholarPubMed
Shibasaki, H. Neurophysiological classification of myoclonus. Neurophysiol Clin. 2006;36:2679.CrossRefGoogle ScholarPubMed
Kojovic, M, Cordivari, C, Bhatia, K. Myoclonic disorders: a practical approach for diagnosis and treatment. Ther Adv Neurol Disord. 2011;4:4762.CrossRefGoogle ScholarPubMed
Tassinari, CA, Rubboli, G, Shibasaki, H. Neurophysiology of positive and negative myoclonus. Electroencephalogr Clin Neurophysiol. 1998;107:18195.CrossRefGoogle ScholarPubMed
Cruccu, G, Deuschl, G. The clinical use of brainstem reflexes and hand-muscle reflexes. Clin Neurophysiol. 2000;111:37187.CrossRefGoogle ScholarPubMed
Sutton, GG, Mayer, RF. Focal reflex myoclonus. J Neurol Neurosurg Psychiatry. 1974;37:20717.CrossRefGoogle ScholarPubMed
Monza, D, Ciano, C, Scaioli, V, et al. Neurophysiological features in relation to clinical signs in clinically diagnosed corticobasal degeneration. Neurol Sci. 2003;24:1623.CrossRefGoogle ScholarPubMed
Carella, F, Ciano, C, Panzica, F, Scaioli, V. Myoclonus in corticobasal degeneration. Mov Disord. 1997;12:598603.CrossRefGoogle ScholarPubMed
Okuma, Y, Fujishima, K, Miwa, H, Mori, H, Mizuno, Y. Myoclonic tremulous movements in multiple system atrophy are a form of cortical myoclonus. Mov Disord. 2005;20:4516.CrossRefGoogle ScholarPubMed
Caviness, JN, Adler, CH, Newman, S, Caselli, RJ, Muenter, MD. Cortical myoclonus in levodopa-responsive Parkinsonism. Mov Disord. 1998;13:5404.CrossRefGoogle ScholarPubMed
Hughes, AJ, Lees, AJ, Daniel, SE, Blankson, S. A clinicopathologic study of 100 cases of Parkinson’s disease. Arch Neurol. 1993;50:1408.CrossRefGoogle ScholarPubMed
Glass, GA, Ahlskog, JE, Matsumoto, JY. Orthostatic myoclonus: a contributor to gait decline in selected elderly. Neurology. 2007;68:182630.CrossRefGoogle ScholarPubMed
Gunduz, A, Tutuncu, M, Zeydan, B, et al. Electrophysiological investigations in orthostatic myoclonus : preliminary findings. Can J Neurol Sci. 2017;45:14.Google ScholarPubMed
Guerrini, R, Bonanni, P, Parmeggiani, L, Santucci, M. Cortical reflex myoclonus in rett syndrome 1998;, 4729.CrossRefGoogle Scholar
Li, JY, Cunic, DI, Paradiso, G, et al. Electrophysiological features of myoclonus-dystonia. Mov Disord. 2008;23:205561.CrossRefGoogle ScholarPubMed
Marelli, C, Canafoglia, L, Zibordi, F, et al. A neurophysiological study of myoclonus in patients with DYT11 myoclonus-dystonia syndrome. Mov Disord. 2008;23:20418.Google ScholarPubMed
Canafoglia, L, Ciano, C, Panzica, F, et al. Sensorimotor cortex excitability in Unverricht-Lundborg disease and Lafora body disease. Neurology. 2004;63:230915.CrossRefGoogle ScholarPubMed
Visani, E, Canafoglia, L, Sebastiano, DR, et al. Clinical neurophysiology giant SEPs and SEP-recovery function in Unverricht – Lundborg disease. Clin Neurophysiol. 2013;124:10138.CrossRefGoogle ScholarPubMed
Canafoglia, L, Franceschetti, S, Uziel, G, et al. Characterization of severe action myoclonus in sialidoses. Epilepsy Res. 2011;94:8693.CrossRefGoogle ScholarPubMed
Demura, A, Demura, Y, Ota, M, Kondo, T, Kinoshita, M. Clinical significance of the long-loop reflex and giant evoked potentials in genetically proven benign adult familial myoclonic epilepsy. Clin Neurophysiol. 2020;131:97880.CrossRefGoogle ScholarPubMed
Manabe, Y, Narai, H, Warita, H, et al. Benign adult familial myoclonic epilepsy (BAFME) with night blindness. Seizure. 2002;11:2668.CrossRefGoogle ScholarPubMed
Noth, J, Friedemann, H-H, Podoll, K, Lange, HW. Absence of long latency reflexes to imposed finger displacements in patients with Huntington’s disease. Neurosci Lett. 1983;35:97100.CrossRefGoogle ScholarPubMed
Thompson, PD, Berardelli, A, Rothwell, JC, et al. The coexistence of bradykinesia and chorea in Huntington’s disease and its implications for theories of basal. Brain. 1988;111:22344.CrossRefGoogle ScholarPubMed
Noth, J, Podoll, K, Friedemann, H. Long-loop reflexes in small hand muscles studied in normal subjects and in patients with Huntington’s disease. Brain. 1985;108:6580.CrossRefGoogle ScholarPubMed
Eisen, A, Bohlega, S, Hayden, M. Silent periods, long-latency reflexes and cortical MEPs in Huntington’s disease arid at-risk relatives. Electroencephalogr Clin Neurophysiol. 1989;9:4449.Google Scholar
Deuschl, G, Lucking, CH, Schenck, E. Hand muscle reflexes following electrical stimulation in choreatic movement disorders. J Neurol Neurosurg Psychiatry. 1989;52:75562.CrossRefGoogle ScholarPubMed
Lefaucheur, JP, Menard-Lefaucheur, I, Maison, P, et al. Electrophysiological deterioration over time in patients with Huntington’s disease. Mov Disord. 2006;21:13504.CrossRefGoogle ScholarPubMed
Rossi Sebastiano, D, Soliveri, P, Panzica, F, et al. Cortical myoclonus in childhood and juvenile onset Huntington’s disease. Park Relat Disord. 2012;18:7947.CrossRefGoogle ScholarPubMed
Huttunen, J, Homberg, V. EMG responses in leg muscles to postural perturbations in Huntington’s disease. J Neurol Neurosurg Psychiatry. 1990;53:5562.CrossRefGoogle ScholarPubMed
Deuschl, G, Lvjcking, CH, Schenckt, E. Essential tremor: electrophysiological and pharmacological evidence for a subdivision. J Neurol Neurosurg Psychiatry. 1987;50:143541.CrossRefGoogle ScholarPubMed
Elble, RJ, Higgins, C, Moody, CJ. Stretch reflex oscillations and essential tremor. J Neurol Neurosurg Psychiatry. 1987;50:6918.CrossRefGoogle ScholarPubMed
Markand, ON. Familial startle disease (hyperexplexia). Arch Neurol. 1984;41:71.CrossRefGoogle ScholarPubMed
Brown, P, Rothwell, JC, Thompson, PD, Britton, TC, Day, BL, Marsden, CD. The hyperekplexias and their relationship to the normal startle reflex. Brain. 1991;114:190328.CrossRefGoogle Scholar
Luiz, J, Gherpelli, D, Reis, A, et al. Hyperekplexia, a cause of neonatal apnea: a case report. Brain Dev. 1995;17:1146.Google Scholar
Köster, B, Lauk, M, Timmer, J, et al. Central mechanisms in human enhanced physiological tremor. Neurosci Lett. 1998;241:1358.CrossRefGoogle ScholarPubMed
Matthews, PB, Farmer, SF, Ingramt, DA. On the localization of the stretch reflex of intrinc muscles in a patient with mirror movements. Physiology. 1990;428:56177.Google Scholar
Srinivasulu, B, Lakshmi, PV, Borgohain, R. Electrophysiological study of Writer’s cramp 2018;, 17(2):17.Google Scholar
Lee, YC, Chen, JT, Liao, KK, Wu, ZA, Soong, BW. Prolonged cortical relay time of long latency reflex and central motor conduction in patients with spinocerebellar ataxia type 6. Clin Neurophysiol. 2003;114:45862.CrossRefGoogle ScholarPubMed
Naumann, M, Reiners, K. Long-latency reflexes of hand muscles in idiopathic focal dystonia and their modification by botulinum toxin. Brain. 1997;120:40916.CrossRefGoogle ScholarPubMed
Striano, P, Manganelli, F, Boccella, P, Perretti, A, Striano, S. Levetiracetam in patients with cortical myoclonus: a clinical and electrophysiological study 2005, 20(12):16104.CrossRefGoogle Scholar
Dueschl, G, Strahl, K, Schenck, E, Lücking, CH. The diagnostic significance of long-latency reflexes in multiple sclerosis. Electroencephalogr Clin Neurophysiol. 1988;70:5661.CrossRefGoogle Scholar
Bonfiglio, L, Rossi, B, Sartucci, F. Prolonged intracortical delay of long-latency reflexes: electrophysiological evidence for a cortical dysfunction in multiple sclerosis 2006;, 69:60613.CrossRefGoogle Scholar
Iovichich, A. Long latency reflexes and somatosensory potentials in multiple sclerosis patients 1994;, 24(5):212.CrossRefGoogle Scholar
Michels, R, Wessel, K. Long-latency reflexes, somatosensory evoked potentials and transcranial magnetic stimulation: relation of the three methods in multiple sclerosis 1993;, 89:23541.CrossRefGoogle Scholar
Matsumoto, H, Kaneshige, Y. Correlation of somatosensory evoked potentials and long loop reflexes in patients with multiple sclerosis. J Neurol Sci. 1990;95:33543.CrossRefGoogle ScholarPubMed
Toydemİr, HE, Gökyİğİt, M, Seleker, FK, Çelebİ, LG. Long-latency reflexes and area measurements of corpus callosum in patients with multiple sclerosis. Bezmialem Sci. 2016 511.CrossRefGoogle Scholar
Friedemann, H H, Noth, J, Diener, H C, Bacher, M. Long latency EMG responses in hand and leg muscles: cerebellar disorders. J Neurol Neurosurg Psychiatry. 1987;50:717.CrossRefGoogle ScholarPubMed
Diener, HC, Dichgans, J, Bacher, M, Guschlbauer, B. Characteristic alterations of long-loop “reflexes” in patients with Friedreich’s disease and late atrophy of the cerebellar anterior lobe. J Neurol Neurosurg Psychiatry. 1984;47:67985.CrossRefGoogle ScholarPubMed
Chandra, SR, Isaac, TG, Mane, M, Bharath, S, Nagaraju, BC. Long loop reflex 2 in patients with cortical dementias: a pilot study. Indian J Psychol Med. 2017;39:1648.CrossRefGoogle ScholarPubMed
Stetkarova, I, Stejskal, L, Kofler, M. Tumors localized near the central sulcus may cause increased somatosensory evoked potentials. Clin Neurophysiol. 2006;117:135966.CrossRefGoogle ScholarPubMed
Gündüz, A, Kiziltan, ME, Coşkun, T, Delil, Ş, Yeni, N, Özkara, Ç. Electrophysiological findings in Rasmussen’s syndrome. Epileptic Disord. 2016;18:736.CrossRefGoogle ScholarPubMed
Liao, K, Chen, J, Lin, K, Chen, C, Kao, K, Wu, Z. Brain dysfunction explored by long latency reflex: a study of adrenomyeloneuropathy. Acta Neurol Scand. 2001;104:1059.CrossRefGoogle ScholarPubMed
Shields, RK, Petrie, M, Ba, SC, et al. Myotonic dystrophy type 1 alters muscle twitch properties, spinal reflexes, and perturbation-induced trans-cortical reflexes. Muscle Nerve. 2020;61:20512.CrossRefGoogle ScholarPubMed
Faig, J, Busse, O. Silent period evoked by transcranial magnetic stimulation in unilateral thalamic infarcts. J Neurol Sci. 1996;142:8592.CrossRefGoogle ScholarPubMed
Groenewegen, JS, de Groot, JH, Schouten, AC, Maier, AB, Arendzen, JH, Meskers, CGM. Spinal reflex properties in the long term after stroke. J Electromyogr Kinesiol. 2012;22:23442.CrossRefGoogle Scholar
Trumbower, RD, Finley, JM, Shemmell, JB, Honeycutt, CF, Perreault, EJ. Bilateral impairments in task-dependent modulation of the long-latency stretch reflex following stroke 2013;, 124(7):137380.CrossRefGoogle Scholar
Banks, CL, Little, VL, Walker, ER, Patten, C. Lower extremity long-latency reflexes differentiate walking function after stroke. Exp Brain Res. 2019;237:2595605.CrossRefGoogle ScholarPubMed
Bartel, P, Lotz, B, Delpori, R, Ubbink, J, Becker, P. Electrophysiological indices of central and peripheral nervous system function during theophylline therapy. Neuropsychobiology. 1989;21:1048.CrossRefGoogle ScholarPubMed
Mashhadi Malek, M, Towhidkhah, F, Gharibzadeh, S, Daeichin, V, Ali Ahmadi-Pajouh, M. Are rigidity and tremor two sides of the same coin in Parkinson’s disease? Comput Biol Med. 2008;38:11339.Google ScholarPubMed
Oepen, G, Doerr, M, Thoden, U. Visual (VEP) and somatosensory (SSEP) evoked potentials in Huntington’s chorea. Electroencephalogr Clin Neurophysiol. 1981;51:66670.CrossRefGoogle ScholarPubMed
Noth, J, Engel, L, Friedemann, HH, Lange, HW. Evoked potentials in patients with Huntington’s disease and their offspring. I. Somatosensory evoked potentials. Electroencephalogr Clin Neurophysiol Evoked Potentials Section. 1984;59:13441.Google ScholarPubMed
Wiesendanger, M, Miles, TS. Ascending pathway of low-threshold muscle afferents to the cerebral cortex and its possible role in motor control. Physiol Rev. 1982;62:123470.CrossRefGoogle Scholar
Marsden, CD, Rothwell, JC, Day, BL. Long-latency automatic responses to muscle stretch in man: origin and function. Adv Neurol. 1983;39:50939.Google ScholarPubMed
Töpper, R, Schwarz, M, Lange, HW, Hefter, H, Noth, J. Neurophysiological abnormalities in the Westphal variant of Huntington’s disease. Mov Disord. 1998;13:9208.CrossRefGoogle ScholarPubMed
Park, H, Kim, H. Electrophysiologic assessments of involuntary movements: tremor and myoclonus. J Mov Disord. 2009;2:147.Google ScholarPubMed
Balestra, C, Levenez, M, Lafere, P, Dachy, B, Ezquer, M, Germonpre, P. Respiratory rate can be modulated by long-loop muscular reflexes, a possible factor in involuntary cessation of apnea. Diving Hyperb Med. 2014;1:38.Google Scholar
Oostveen, CN, Weerwind, PW, Bergs, PPE, et al. Neurophysiological and paraspinal oximetry monitoring to detect spinal cord ischemia in patients during and after descending aortic repair: an international multicenter explorative study. Contemp Clin Trials Commun. 2020;17:100545.CrossRefGoogle ScholarPubMed
Figure 0

Figure 1: Long Latency reflex (LLR) transduction pathway and the levels involved in various clinical conditions. 1: Parkinson’s disease (PD), 1A: Abnormal Basal ganglia output leading to impaired modulation of transcortical pathways, 1B: Increased transmission by Group II afferents in PD, 1C: Altered excitability of spinal interneurons, 2: Cortical excitability in myoclonus, 3: Huntington’s disease (HD), reduced impulse transmission to the cortex at the thalamic or thalamocortical projection level 3A: Degeneration of neurons at Thalamus in HD, 3B: Degeneration of neurons in the cortico-cortical pathways in HD, 4: Impaired transmission of impulses along the ascending and descending fibres due to demyelinating plaques in Multiple Sclerosis. The figure was created with BioRender.com.

Figure 1

Figure 2: Search strategy and study selection in accordance with Systematic review without meta-analysis (SWiM) guidelines.

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Table 1: Studies of LLR in Parkinsonian disorders

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Table 2: Studies of LLR in myoclonus

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Table 3: Studies of LLR in Huntington’s disease

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Table 4: Studies of LLR in Multiple sclerosis