Physiologic and anatomic basis for contralateral R1 in blink reflex

The blink reflex and its modulation - Part 1: Physiological mechanisms

The blink reflex (BR) is a protective eye-closure reflex mediated by brainstem circuits. The BR is usually evoked by electrical supraorbital nerve stimulation but can be elicited by a variety of sensory modalities. It has a long history in clinical neurophysiology practice. Less is known, however, about the many ways to modulate the BR. Various neurophysiological techniques can be applied to examine different aspects of afferent and efferent BR modulation. In this line, classical conditioning, prepulse and paired-pulse stimulation, and BR elicitation by self-stimulation may serve to investigate various aspects of brainstem connectivity. The BR may be used as a tool to quantify top-down modulation based on implicit assessment of the value of blinking in a given situation, e.g., depending on changes in stimulus location and probability of occurrence. Understanding the role of non-nociceptive and nociceptive fibers in eliciting a BR is important to get insight into the underlying neural circuitry. Finally, the use of BRs and other brainstem reflexes under general anesthesia may help to advance our knowledge of the brainstem in areas not amenable in awake intact humans. This review summarizes talks held by the Brainstem Special Interest Group of the International Federation of Clinical Neurophysiology at the International Congress of Clinical Neurophysiology 2022 in Geneva, Switzerland, and provides a state-of-the-art overview of the physiology of BR modulation. Understanding the principles of BR modulation is fundamental for a valid and thoughtful clinical application (reviewed in part 2) (Gunduz et al., submitted).

Late-onset neurological symptoms in thalidomide-exposed subjects: a study of an Australasian cohort

BACKGROUND AND PURPOSE

Thalidomide was marketed for the treatment of morning sickness and resulted in foetal death and physical deformities. The exact mechanism of action of thalidomide in its teratogenicity is still actively debated in the literature.

METHODS

This study reviewed 16 of the confirmed Australasian victims of in utero exposure to thalidomide who now presented with new-onset neurological symptoms in the fourth and fifth decades.

RESULTS

Clinical neurological examination and neurophysiological investigations revealed that new symptoms were due in part to compressive neuropathies, often exacerbated by the adaptations made to accommodate the disability and poor mobility arising from the limb deformities. Other subjects were found to have musculoskeletal symptoms due to compensatory postures employed to perform tasks of daily living.

CONCLUSIONS

The study provides no evidence of ongoing loss of neurons or late reactivated neural degeneration and no evidence of a generalized peripheral neuropathy. Rather, the development of new symptoms in subjects can be explained by compressive neuropathies and compensatory postures employed to perform tasks of daily living.

Electrophysiological Evaluation of Cranial Neuropathies

BACKGROUND

Cranial nerve abnormalities occur frequently in both focal and diffuse neurologic disorders and can be evaluated by electrophysiological techniques available in most clinical neurophysiology laboratories.

REVIEW SUMMARY

The optic nerve is evaluated by visual evoked potentials. Measurements of latency, amplitude, and waveform morphology are especially useful in detecting demyelinating lesions. Brain stem auditory evoked potentials evaluate the auditory portion of the eighth cranial nerve. Using an auditory stimulus, a number of waveforms are generated, and changes in the normal patterns of response can detect abnormalities. Assessment of the trigeminal and facial nerves is done using a series of electrical stimulation techniques including the blink, masseter, and masseter inhibitory reflexes and facial motor nerve conduction studies. The blink reflex detects lesions of the first division of the trigeminal nerve and the facial nerve. The masseter reflex evaluates the third division of the trigeminal nerve. Changes in responses are measured and, using a combination of these techniques, localization of lesions at specific sites can be made. Accessory motor nerve conduction is useful not only in focal nerve injury, but repetitive stimulation on the accessory and facial nerves is used in diagnosing neuromuscular junction disorders. In addition, many of the voluntary muscles innervated by the cranial nerves are accessible to needle electrode examination, and evaluation can aid in identification of focal nerve lesions, as well as diagnosis in diffuse nerve and muscle disorders.

CONCLUSION

Electrophysiological techniques offer reliable means of measuring the integrity of the cranial nerves and their central pathways.

A tribute to Jack Petajan's inspiration: From goat to goat

Development of clinical neurophysiology, especially in neuromuscular disease investigation in the 20th century underscores the careers of two academic physician-investigators. Experimental models of neuromuscular disorders (toxic and diabetic neuropathies, myasthenia gravis, nerve transplant and repair) with emphasis on regeneration are described. Subsequent clinical application has validated the animal studies. The value of disease related support societies (Muscular Dystrophy, Charcot Marie Tooth and Myasthenia Gravis) is discussed, not only for patient information and support but also for support of research projects and clinical research fellowship training. The clinician-teacher-investigator as a role model is mentioned, particularly in relation to Dr. Jack Petajan's career, a truly renaissance man. Credit is given to the great teachers of clinical neurophysiology and neuromuscular diseases of the past 50 years.

Influence of stimulus control on the excitability of the electrically elicited blink reflex in patients with schizophrenia

BACKGROUND

In humans, the excitability of the electrically evoked blink reflex is influenced by the subject's attention to the stimulus. The early reflex component R1 has been found to be facilitated in conditions of increased selective attention, whereas the late components R2 and R3 exhibited a marked suppression. Distraction from the stimulus leads to enhanced R2 and R3 magnitudes.

METHODS

We investigated the excitability of the distinct reflex components in 19 patients with schizophrenia and 19 healthy control subjects. In the control condition (EE), stimulation was elicited by the experimenter; in a second condition (SE), subjects released a key to evoke the reflex themselves.

RESULTS

The SE patients with schizophrenia exhibited an abnormally increased R1 facilitation and an impaired R2 inhibition in comparison with normal control subjects. An R3 component could be registered in EE in 13 of 19 patients but only in one control subject; SE resulted in a complete suppression of this component in all but two patients with schizophrenia.

CONCLUSIONS

The abnormal R1 facilitation and the impaired R2 inhibition may be regarded as neurophysiological markers of defective information processing in a condition of increased selective attention to a self-controlled stimulus in patients with schizophrenia. The enhanced excitability of the R3 component under standard conditions indicates defective attentional mechanisms in patients with schizophrenia in an uninstructed passive condition attending a stimulus triggered by the experimenter.

A neurophysiological approach to brainstem reflexes. Blink reflex

The blink reflex (BR) is a generalised phenomenon in mammals. Its teleological protective eye function is perhaps the reason why the BR can be provoked by a multitude of stimuli. As corneal and glabellar reflexes, BR has an inveterate use in the neurological exploration. Some of its physiopathological aspects were discussed more than 100 years ago, and soon half a century will have passed since the first electrophysiological study was published. This review focuses on the BR elicited by the electrical stimulation of the trigeminal supraorbital nerve, a controlled and reliable model in clinical neurophysiology. The electrically elicited BR is an exteroceptive-nociceptive reflex recorded on the orbicularis oculi muscle and formed by three components: the two principal ones, R1 and R2, of well-known characteristics, and a third, R3, of increasing interest, to which there is wide mention. The trigeminal afferent limb reaches the facial efferent one by means of a long and quite complex central pathway located at the brainstem bulbopontine level. The anatomical substrate and criteria of the rich topographical lesional semiology of the BR are established. The importance of the suprasegmental influences upon the reflex, coming mainly from the cerebral cortex and basal ganglia, as well as the impairment caused by their damage, will be emphasised. Special attention is paid to the relationship between the reflex and the dopaminergic system, and the consequences of its derangement. The methods of habituation and suppression-recovery of the BR are extensively and critically reviewed. These methods measure its excitability and serve in practice for the pathophysiological study of numerous diseases. The relationship of the BR with the spontaneous blinking is considered, and the existence of a primary inhibitory reflex on levator palpebrae muscles, previous to the active reflex response of the orbicularis, is proposed. The electrophysiological characteristics of the glabellar reflex, the corneal reflex, the acoustic, photic and somatosensory provoked BR, the ontogeny, and some of the common factors influencing the reflex, such as sleep, are also discussed. The strategic position of the neural structures of the BR, in an area involved in the gating of the various sensory-motor systems and the relative ease to its evaluation with common methodology used in clinical neurophysiology, makes the BR an essential tool for the diagnosis and pathophysiological insight into an important number of human neurological disorders.

Blink reflex with stimulation of the mental nerve. Methodology, reference values, and some clinical vignettes

INTRODUCTION

In order to develop an objective electrophysiological method for detecting and grading lesions in the inferior alveolar nerve (IAN) and its terminal branch, the mental nerve (MN), the normal physiology of the blink reflex (BR) with stimulation of the distribution of the MN was evaluated and reference values for the MN BR test obtained.

MATERIAL AND METHODS

The BR responses to electrical stimulation of the distribution of the MN on each side were recorded in all 44 healthy adults. The onset latencies and peak-to-peak amplitudes were measured and analysed. The effects of the stimulation site, the size of the stimulating electrode, and facilitation by eye closure and mathematical task on the MN BR responses were tested.

RESULTS

A small paediatric stimulating electrode was found to be efficient for dermatomal stimulation of the MN distribution. The MN BR responses consisted of an ipsilateral late component (R2i) on the side of the stimulation and a contralateral component (R2c) with similar latency. The latencies were longer and the stimulation thresholds needed to evoke a reflex response were higher with stimulation of the MN, when compared with the BRs with supraorbital nerve stimulation. Eye closure resulted in facilitation of the MN BR in the form of latency shortening, while mathematical task did not have any significant effect on the responses. In addition, the test was found useful in the diagnosis of iatrogenic IAN lesions after extraction of third molars in two patients, and after an orthognathic operation in one patient.

CONCLUSION

Contrary to some previous reports, constant MN BR responses can be elicited in healthy adults, which enables further clinical application of this test.

Contralateral early blink reflex in patients with HTLV-I associated myelopathy/tropical spastic paraparesis

Thirty-two Japanese patients with HTLV-I-associated myelopathy/tropical spastic paraparesis (HAM/TSP) were studied by means of the electrically elicited blink reflex and three responses (R1, R2, R3) were registered. 69% of the patients displayed a uni- or bilateral crossed R1 response (R1k) as compared to 11% in the control group. A positive correlation between R1k and an exaggerated jaw jerk reflex was found in the patients. Central abnormalities of the nervous system with diminished presynaptic inhibition acting in the interneuronal input of the brainstem of HAM/TSP patients was the most likely cause. It could lead to the unmasking of crossed trigemino-facial pathway reflex which is present in the normal population from birth. These results strongly support the supraspinal involvement of the central nervous system (CNS) in HAM/TSP more than usually thought.

Contralateral early blink reflex in patients with facial nerve palsy: indication for synaptic reorganization in the facial nucleus during regeneration

Fifty patients with Bell's palsy and 30 patients with etiologically different symptomatic peripheral facial nerve palsy were studied by means of electrically evoked blink reflexes 1-23 days after onset of paresis. Their results were compared with a normal control group of 30 healthy subjects. In a significant number of patients (64% in Bell's palsy and 53% in symptomatic facial nerve palsy) a contralateral early blink reflex response (R1) could be elicited upon stimulation of the normal side as compared to 13% in the control group. It is suggested that this result may be explained by synaptic reorganization of the facial nucleus leading to functional unmasking of pre-existing crossed trigemino-facial reflex pathways during regeneration. This view is in line with previous experimental data in animals on the time course of structural changes in the facial nucleus after lesioning of the ipsilateral facial nerve.