Scratch reflex
The scratch reflex is a response to activation of sensory neurons whose peripheral terminals are located on the surface of the body.[1] Some sensory neurons can be activated by stimulation with an external object such as a parasite on the body surface. Alternatively, some sensory neurons can respond to a chemical stimulus that produces an itch sensation. During a scratch reflex, a nearby limb reaches toward and rubs against the site on the body surface that has been stimulated. The scratch reflex has been extensively studied to understand the functioning of neural networks in vertebrates.[2] Despite decades of research, key aspects of the scratch reflex are still unknown, such as the neural mechanisms by which the reflex is terminated. This article will focus on the neurological aspects of the reflex.
Model systems and tools
Animal models and preparations
A number of animal models have been used to study, understand and characterize the scratch reflex. These models include the turtle, cat, frog, dog, and a variety of other vertebrates.[1][2][3][4] In these studies, researchers made use of spinal preparations, which involve a complete transection of the animal's spinal cord prior to experimentation.[1] Such preparations are used because the scratch reflex can be elicited and produced without the involvement of supraspinal structures.[1] Researchers focused predominantly on investigating spinal cord neural circuitry responsible for the generation of the scratch reflex, limiting the system of study.
In studies of spinal preparations, researchers have experimented using preparations both with and without movement-related sensory inputs.[1][2] In preparations with movement-related sensory inputs, the muscles and the motor neuron outputs to muscles are left intact, allowing sensory feedback from the moving limb. In preparations without movement-related sensory input, either of three strategies are used: (1) the axons of sensory neurons are cut by dorsal root transection; or (2) neuromuscular blockers are used to prevent contractions of muscles in response to motor neuron activity; or (3) the spinal cord is isolated in a bath of physiological saline.[1]
Recording techniques
Electromyographic (EMG) and electroneurographic (ENG) techniques are used to monitor and record from animals during experiments.[5] EMG recordings are used to record electrical activity directly from muscles. ENG recordings are used to record electrical activity from motor neurons and spinal cord neurons.[6] These techniques have enabled researchers to understand the neural circuitry of the scratch reflex on a single-cell level.
Characteristics
General
The scratch reflex is generally a rhythmic response. Results from animal studies have indicated that spinal neural networks known as central pattern generators (CPGs) are responsible for the generation and maintenance of the scratch reflex.[1][7][8][9] One feature of the scratch reflex is that supraspinal structures are not necessary for the generation of the reflex. The scratch response is programmed into the spinal cord, and can be produced in spinal animals.
Another feature of the scratch reflex is that the spinal CPGs which generate and maintain the reflex are capable of producing the reflex in the absence of movement-related sensory feedback.[1][2] This discovery was made while studying animals with silenced afferent neurons from the scratching limb, meaning no movement-related sensory feedback was available to the spinal circuits driving the scratch. Amazingly, these animals were capable of producing a functional scratch response, albeit diminished in accuracy. When afferent feedback is provided, the scratch response is more accurate in terms of accessing the stimulus site. Recordings indicate that feedback modulates the timing and intensity of scratching, in the form of phase and amplitude changes in nerve firing.[2]
In studying the scratch reflex, researchers have named a number of regions on the surface of the body as they relate to the reflex.[8] A pure form domain is a region on the surface of the body, that when stimulated, elicits only one form of the scratch reflex. A form is a movement-related strategy used by the animal to perform the scratch; for example, to scratch the upper back, humans are limited to one scratch form, involving the elbow raised above the shoulder to provide access to the upper back. In addition to pure form domains, there also exist a number of transition zones, which can be successfully targeted by more than one form of the reflex, and which usually lie at the boundary of two pure form domains.
Researchers have also developed terms to describe the scratch reflex movements themselves.[8] A pure movement is one in which only one form of the scratch response is utilized to respond to the stimulus. A switch movement occurs in a transition zone, and is characterized by the smooth switching between two different scratch forms in response to the stimulus. A hybrid movement is observed and occurs at transition zones as well, and is characterized by two rubs during each scratch cycle, where each rub is derived from one pure form movement. Research on hybrid and switch movements at transition zones indicates that the CPGs responsible for scratch generation are modular and share interneurons. For this reason, in both the switch and hybrid movements, the path of the moving limb is smooth and uninterrupted.
Studies from EMG recordings have indicated that reciprocal inhibition between hip-related interneurons in the CPG for the scratch reflex is not necessary for the production and maintenance of the hip-flexor rhythm that is a key part of the scratch reflex.[8] This research further supports the findings on switch and hybrid movements, which suggest a modular organization of unit generator CPGs used in combination to achieve a task.
Another general aspect of the scratch response is that the response continues even after afferent input from the stimulated zone ceases.[9] For a few seconds after the cessation of the scratch, the neural networks involved in the generation of the scratch reflex remain in a state of heightened sensitivity. During this period of increased excitability, stimuli normally too weak to trigger a scratch response are capable of eliciting a scratch response in a site specific manner. That is, stimuli, too weak to elicit the scratch response when applied in a rested preparation, are capable of eliciting the scratch response during the period of increased excitability just following a scratch response. This excitability is due, in part, to the long time constant of NMDA receptors. Research has also shown that voltage-gated calcium channels have a role in the increased excitability of spinal neurons.[2]
Spinal
As described in the general characteristics above, the scratch reflex is programmed into the neural circuitry of the spinal cord. Initial experiments on the scratch reflex in dogs revealed that the spinal cord has circuits capable of summing inputs. This ability of the spinal cord was discovered when stimuli, on their own too weak to generate a response, were capable of eliciting a scratch response when applied in a quick succession.[4]
Additionally, studies involving successive spinal transections in a turtle model have identified that spinal CPGs are distributed throughout the spinal segments asymmetrically.[7] Furthermore, the site specificity of the scratch response indicates that the spinal circuitry also has a built in map of the body. This allows the spinal CPGs to generate a scratch response targeted to the site of the stimulus independent of supraspinal structures.
Research into form selection has revealed that form selection is also intrinsic to the spinal cord.[7] More recent research suggests that form selection is accomplished using the summed activities of populations of broadly tuned interneurons shared by various unit CPGs.[10] Additionally, intracellular recordings have illustrated that motor neurons receive at least two types of inputs from spinal CPGs. These inputs include inhibitory postsynaptic potentials (IPSPs) and excitatory postsynaptic potentials (EPSPs), meaning that scratch CPGs are responsible for both the activation and deactivation of muscles during the scratch response.
Very recent research suggests that the scratch reflex shares interneurons and CPGs with other locomotor tasks such as walking and swimming.[10] The findings from these studies also suggests that mutual inhibition between networks may play a role in behavioral choice in the spinal cord. This finding is supported by earlier observations on the scratch reflex, which indicate that the scratch reflex was particularly difficult to induce in animals already involved in a different locomotive task, such as walking or swimming.[2]
Supraspinal
While the scratch reflex can be produced without supraspinal structures, research indicates that neurons in the motor cortex play a role in the modulation of the scratch reflex as well.[3] Stimulation of pyramidal tract neurons has been found to modulate the timing and intensity of scratch reflex. Furthermore, extensive research has identified the involvement of supraspinal structures in the modulation of the rhythmic elements of the scratch reflex. The current theory is that efference copies from CPGs travel to the cerebellum via spinocerebellar pathways. These signals then modulate the activity of the cerebellar cortex and nuclei, which in turn regulate descending tract neurons in the vestibulospinal, reticulospinal, and rubrospinal tracts.[11][12][13][14] Presently, there is not much else known about the specifics of supraspinal control of the scratch reflex.
See also
References
- 1 2 3 4 5 6 7 8 Stein, P. S. G. (1983). The vertebrate scratch reflex. Symposia of the Society for Experimental Biology(37), 383–403
- 1 2 3 4 5 6 7 Stein, P. (2005). Neuronal control of turtle hindlimb motor rhythms. Journal of Comparative Physiology A Neuroethology Sensory Neural Behavioral Physiology 191: 213–229
- 1 2 Sirota, M. G., Pavlova, G. A., & Beloozerova, I. N. (2006). Activity of the motor cortex during scratching. Journal of Neurophysiology, 95(2), 753–765.
- 1 2 Sherrington CS (1906a) Observations on the scratch-reflex in the spinal dog. J Physiol 34:1–50
- ↑ Robertson, G. A., & Stein, P. S. G. (October 1988). "Synaptic control of hindlimb motoneurones during three forms of the fictive scratch reflex in the turtle". Journal of Physiology: 101–128. PMID 3253428.
- ↑ Earhart, G. M., & Stein, P. S. G. (2000). Step, swim, and scratch motor patterns in the turtle. Journal of Neurophysiology, 84(5), 2181–2190.
- 1 2 3 Mortin, L. I., & Stein, P. S. G. (1989). "Spinal cord segments containing key elements of the central pattern generators for three forms of scratch reflex in the turtle". Journal of Neuroscience, 9(7), 2285–2296.
- 1 2 3 4 Stein, P.S.G. (2003) Scratch reflex. The Handbook of Brain Theory and Neural Networks 2nd Edition, ed. by M.A. Arbib, MIT Press, Cambridge, pp. 999–1001
- 1 2 Stein, P.S.G. (2004) Scratch reflex. In Encyclopedia of Neuroscience, Third Edition CD-ROM, ed. by G. Adelman and B.H. Smith, Elsevier, Oxford.
- 1 2 Berkowitz, A. (2008). Physiology and morphology of shared and specialized spinal interneurons for locomotion and scratching. Journal of Neurophysiology, 99(6), 2887–2901.
- ↑ Arshavsky, Y. I., Gelfand, I. M., Orlovsky, G. N., & Pavlova, G. A. (1978a). MESSAGES CONVEYED BY DESCENDING TRACTS DURING SCRATCHING IN THE CAT .1. ACTIVITY OF VESTIBULOSPINAL NEURONS. Brain Research, 159(1), 99–110.
- ↑ Arshavsky, Y. I., Gelfand, I. M., Orlovsky, G. N., & Pavlova, G. A. (1978b). MESSAGES CONVEYED BY SPINOCEREBELLAR PATHWAYS DURING SCRATCHING IN CAT .1. ACTIVITY OF NEURONS OF LATERAL RETICULAR NUCLEUS. Brain Research, 151(3), 479–491.
- ↑ Arshavsky, Y. I., Gelfand, I. M., Orlovsky, G. N., & Pavlova, G. A. (1978c). MESSAGES CONVEYED BY SPINOCEREBELLAR PATHWAYS DURING SCRATCHING IN CAT .2. ACTIVITY OF NEURONS OF VENTRAL SPINOCEREBELLAR TRACT. Brain Research, 151(3), 493–506.
- ↑ Arshavsky, Y. I., Orlovsky, G. N., Pavlova, G. A., & Perret, C. (1978). MESSAGES CONVEYED BY DESCENDING TRACTS DURING SCRATCHING IN THE CAT .2. ACTIVITY OF RUBROSPINAL NEURONS. Brain Research, 159(1), 111–123.