Balance and motor coordination are critical components involved in control of movement. We currently understand the basic mechanisms of the numerous sensory and processing systems that help us maintain our balance while performing various activities. To our advantage, laboratory animals, such as mice, use similar systems for maintaining balance and motor coordination. Scientists can therefore use mice to model different physiological conditions to observe their effect in balance and motor coordination tests.
This video will briefly discuss the neurophysiology behind balance and coordination, followed by the general protocols for the most commonly used behavioral tests, namely the rotarod and balance beam. Lastly, we'll review some current experiments being conducted using these behavioral paradigms.
Before delving into the protocols of behavioral tests, let's take a look at the neurophysiological inputs and processing units that determine our balance and motor coordination.
Visual cues combined with the innate sense of our body's position in space, also known as proprioception, are the main sensory inputs determining our balance. The receptors involved in this phenomenon, called proprioceptors, are found in muscles and joints, and they provide information about our physical status to the central nervous system. This information, combined with input from the vestibular system, which is housed in our inner ear, make up the rest of our "proprioceptive sense." The vestibular system is made up of three semicircular ducts capped by an ampulla, which together are known as canals. Contained within these canals is a fluid called endolymph. A specialized structure known as the cupula, located within the ampulla of each canal, contains hair cells that produce cilia. It is these cilia that are bent by moving endolymph and transmit that information to the vestibular nuclei, which are located in the brainstem. In the brainstem, inputs from the eyes, joints, and vestibular system are sorted and prioritized.
Finally, all these sensory inputs travel to the cerebellum, which subconsciously coordinates proprioceptive and visual information to fine-tune motor commands to increase muscle precision and coordination. Although, a lot has been discovered about the neurological basis of balance and coordination, scientists are still trying to understand the pathophysiology of various movement disorders. One of the tools used by researchers to do that is the rodent behavioral test examining balance and coordination.
Let's discuss the most commonly employed test for this phenomenon-the rotarod.
The rotarod apparatus is composed of three components. First, the spinning dowel, which comes in various sizes. Second, lanes with divisions: the apparatus may be composed of multiple lanes, which allow researchers to test up to five animals at once, or just a single lane for testing one animal at a time. Third, the platforms located beneath each lane that provide a safe landing zone for the animal if they fall from the spinning dowel. In more modern equipment, these platforms can sense animal falling, and automatically record the "time to fall."
Prior to training or experimentation, a period of acclimatization ensures that animals are in a calm state before testing. Training sessions involve animals walking on an accelerating rotarod for several sessions per day over a series of days, and is considered complete once the animals' average "time to fall" begins to plateau. Initially, the rotarod is set to a low speed while animals are placed on the dowel, and rotation is then gradually increased to a maximum speed. Mice should be allowed to rest in-between training runs, and during that time the apparatus should be thoroughly cleaned.
Following training, experimental interventions, such as drug treatment, surgically induced lesions, or other physical manipulation, can be performed. For testing, follow the same protocol as the training session where dowel speed is gradually increased and the data are recorded as "time to fall." A maximum testing time should be defined so as to not overexert the animals. "Time to fall" for each mouse is recorded and averaged over different numbers of trials depending on the experiment.
The second common behavioral assay that tests balance and coordination uses a beam. Numerous distinct balance beams exist including simple, complex, and slanted beams, but the basic set-up is composed of a one-meter-long beam suspended 50-100 centimeters above a table or surface. Motion sensors or video recorders are present to measure animal beam traversal time. An enclosed box containing nesting material located at the end point serves as an attraction for the mouse, while illumination at the start point would act as an aversive stimulus.
Training on the balance beam usually occurs up to three times per day over several days. Training continues until average beam traversal time begins to plateau; however, overtraining can lead to increased stalling and turning on the beam. Following experimental modulation, the testing phase begins, and data are recorded as "time to traverse." Usually, results are obtained by averaging at least two crossings in which the tested animal did not stop or require prodding.
Now that we've seen the experimental set-ups of commonly employed behavioral tests, let's look at some specific applications of these methods.
Aging is a normal biological process, one consequence of which is the degradation of the vestibular system as hair cells produce fewer cilia, and also begin to die. The result of this is loss of balance that can result in increased falls in the elderly. In this experiment, mice of varying ages went through a vestibular challenge in which they were spun in a rotator for 20 seconds and immediately after that asked to traverse a slanted beam. Researchers observed that older mice are more dramatically affected by vestibular challenge than the younger mice.
Rotarod testing is useful in studying gross motor deficits and fatigue resistance, making it ideal for studying a disease like muscular dystrophy. The hallmark of muscular dystrophy is muscle damage that ultimately results in deficits in mobility, coordination, and balance. In this experiment, researchers compared rotarod running times between wild type mice and mouse models of muscular dystrophy.
Parkinson's disease is characterized by the death of dopaminergic neurons in substantia nigra, and often presents with motor deficits and loss of coordination. In this experiment, a challenging beam test was performed. Comparing wild type mice to a genetically engineered Parkinson's model, it was observed that Parkinson's mice had increased errors per step and increased errors per beam width.
You've just watched JoVE's video on balance and coordination testing. This video discussed the neural correlates of balance and coordination, some prominent methods to test balance, and finally a few applications of these behavioral tests in neuroscience labs today. As always, thanks for watching!
Balance and coordination are critical components involved in the control of movement. Many sensory receptors and neural processing units are required…
Balance and motor coordination are critical components involved in control of movement. We currently understand the basic mechanisms of the numerous sensory and processing systems that help us maintain our balance while performing various activities. To our advantage, laboratory animals, such as mice, use similar systems for maintaining balance and motor coordination. Scientists can therefore use mice to model different physiological conditions to observe their effect in balance and motor coordination tests.
This video will briefly discuss the neurophysiology behind balance and coordination, followed by the general protocols for the most commonly used behavioral tests, namely the rotarod and balance beam. Lastly, we'll review some current experiments being conducted using these behavioral paradigms.
Before delving into the protocols of behavioral tests, let's take a look at the neurophysiological inputs and processing units that determine our balance and motor coordination.
Visual cues combined with the innate sense of our body's position in space, also known as proprioception, are the main sensory inputs determining our balance. The receptors involved in this phenomenon, called proprioceptors, are found in muscles and joints, and they provide information about our physical status to the central nervous system. This information, combined with input from the vestibular system, which is housed in our inner ear, make up the rest of our "proprioceptive sense." The vestibular system is made up of three semicircular ducts capped by an ampulla, which together are known as canals. Contained within these canals is a fluid called endolymph. A specialized structure known as the cupula, located within the ampulla of each canal, contains hair cells that produce cilia. It is these cilia that are bent by moving endolymph and transmit that information to the vestibular nuclei, which are located in the brainstem. In the brainstem, inputs from the eyes, joints, and vestibular system are sorted and prioritized.
Finally, all these sensory inputs travel to the cerebellum, which subconsciously coordinates proprioceptive and visual information to fine-tune motor commands to increase muscle precision and coordination. Although, a lot has been discovered about the neurological basis of balance and coordination, scientists are still trying to understand the pathophysiology of various movement disorders. One of the tools used by researchers to do that is the rodent behavioral test examining balance and coordination.
Let's discuss the most commonly employed test for this phenomenon-the rotarod.
The rotarod apparatus is composed of three components. First, the spinning dowel, which comes in various sizes. Second, lanes with divisions: the apparatus may be composed of multiple lanes, which allow researchers to test up to five animals at once, or just a single lane for testing one animal at a time. Third, the platforms located beneath each lane that provide a safe landing zone for the animal if they fall from the spinning dowel. In more modern equipment, these platforms can sense animal falling, and automatically record the "time to fall."
Prior to training or experimentation, a period of acclimatization ensures that animals are in a calm state before testing. Training sessions involve animals walking on an accelerating rotarod for several sessions per day over a series of days, and is considered complete once the animals' average "time to fall" begins to plateau. Initially, the rotarod is set to a low speed while animals are placed on the dowel, and rotation is then gradually increased to a maximum speed. Mice should be allowed to rest in-between training runs, and during that time the apparatus should be thoroughly cleaned.
Following training, experimental interventions, such as drug treatment, surgically induced lesions, or other physical manipulation, can be performed. For testing, follow the same protocol as the training session where dowel speed is gradually increased and the data are recorded as "time to fall." A maximum testing time should be defined so as to not overexert the animals. "Time to fall" for each mouse is recorded and averaged over different numbers of trials depending on the experiment.
The second common behavioral assay that tests balance and coordination uses a beam. Numerous distinct balance beams exist including simple, complex, and slanted beams, but the basic set-up is composed of a one-meter-long beam suspended 50-100 centimeters above a table or surface. Motion sensors or video recorders are present to measure animal beam traversal time. An enclosed box containing nesting material located at the end point serves as an attraction for the mouse, while illumination at the start point would act as an aversive stimulus.
Training on the balance beam usually occurs up to three times per day over several days. Training continues until average beam traversal time begins to plateau; however, overtraining can lead to increased stalling and turning on the beam. Following experimental modulation, the testing phase begins, and data are recorded as "time to traverse." Usually, results are obtained by averaging at least two crossings in which the tested animal did not stop or require prodding.
Now that we've seen the experimental set-ups of commonly employed behavioral tests, let's look at some specific applications of these methods.
Aging is a normal biological process, one consequence of which is the degradation of the vestibular system as hair cells produce fewer cilia, and also begin to die. The result of this is loss of balance that can result in increased falls in the elderly. In this experiment, mice of varying ages went through a vestibular challenge in which they were spun in a rotator for 20 seconds and immediately after that asked to traverse a slanted beam. Researchers observed that older mice are more dramatically affected by vestibular challenge than the younger mice.
Rotarod testing is useful in studying gross motor deficits and fatigue resistance, making it ideal for studying a disease like muscular dystrophy. The hallmark of muscular dystrophy is muscle damage that ultimately results in deficits in mobility, coordination, and balance. In this experiment, researchers compared rotarod running times between wild type mice and mouse models of muscular dystrophy.
Parkinson's disease is characterized by the death of dopaminergic neurons in substantia nigra, and often presents with motor deficits and loss of coordination. In this experiment, a challenging beam test was performed. Comparing wild type mice to a genetically engineered Parkinson's model, it was observed that Parkinson's mice had increased errors per step and increased errors per beam width.
You've just watched JoVE's video on balance and coordination testing. This video discussed the neural correlates of balance and coordination, some prominent methods to test balance, and finally a few applications of these behavioral tests in neuroscience labs today. As always, thanks for watching!
Balance and motor coordination are critical components involved in control of movement. We currently understand the basic mechanisms of the numerous sensory and processing systems that help us maintain our balance while performing various activities. To our advantage, laboratory animals, such as mice, use similar systems for maintaining balance and motor coordination. Scientists can therefore use mice to model different physiological conditions to observe their effect in balance and motor coordination tests.
This video will briefly discuss the neurophysiology behind balance and coordination, followed by the general protocols for the most commonly used behavioral tests, namely the rotarod and balance beam. Lastly, we'll review some current experiments being conducted using these behavioral paradigms.
Before delving into the protocols of behavioral tests, let's take a look at the neurophysiological inputs and processing units that determine our balance and motor coordination.
Visual cues combined with the innate sense of our body's position in space, also known as proprioception, are the main sensory inputs determining our balance. The receptors involved in this phenomenon, called proprioceptors, are found in muscles and joints, and they provide information about our physical status to the central nervous system. This information, combined with input from the vestibular system, which is housed in our inner ear, make up the rest of our "proprioceptive sense." The vestibular system is made up of three semicircular ducts capped by an ampulla, which together are known as canals. Contained within these canals is a fluid called endolymph. A specialized structure known as the cupula, located within the ampulla of each canal, contains hair cells that produce cilia. It is these cilia that are bent by moving endolymph and transmit that information to the vestibular nuclei, which are located in the brainstem. In the brainstem, inputs from the eyes, joints, and vestibular system are sorted and prioritized.
Finally, all these sensory inputs travel to the cerebellum, which subconsciously coordinates proprioceptive and visual information to fine-tune motor commands to increase muscle precision and coordination. Although, a lot has been discovered about the neurological basis of balance and coordination, scientists are still trying to understand the pathophysiology of various movement disorders. One of the tools used by researchers to do that is the rodent behavioral test examining balance and coordination.
Let's discuss the most commonly employed test for this phenomenon-the rotarod.
The rotarod apparatus is composed of three components. First, the spinning dowel, which comes in various sizes. Second, lanes with divisions: the apparatus may be composed of multiple lanes, which allow researchers to test up to five animals at once, or just a single lane for testing one animal at a time. Third, the platforms located beneath each lane that provide a safe landing zone for the animal if they fall from the spinning dowel. In more modern equipment, these platforms can sense animal falling, and automatically record the "time to fall."
Prior to training or experimentation, a period of acclimatization ensures that animals are in a calm state before testing. Training sessions involve animals walking on an accelerating rotarod for several sessions per day over a series of days, and is considered complete once the animals' average "time to fall" begins to plateau. Initially, the rotarod is set to a low speed while animals are placed on the dowel, and rotation is then gradually increased to a maximum speed. Mice should be allowed to rest in-between training runs, and during that time the apparatus should be thoroughly cleaned.
Following training, experimental interventions, such as drug treatment, surgically induced lesions, or other physical manipulation, can be performed. For testing, follow the same protocol as the training session where dowel speed is gradually increased and the data are recorded as "time to fall." A maximum testing time should be defined so as to not overexert the animals. "Time to fall" for each mouse is recorded and averaged over different numbers of trials depending on the experiment.
The second common behavioral assay that tests balance and coordination uses a beam. Numerous distinct balance beams exist including simple, complex, and slanted beams, but the basic set-up is composed of a one-meter-long beam suspended 50-100 centimeters above a table or surface. Motion sensors or video recorders are present to measure animal beam traversal time. An enclosed box containing nesting material located at the end point serves as an attraction for the mouse, while illumination at the start point would act as an aversive stimulus.
Training on the balance beam usually occurs up to three times per day over several days. Training continues until average beam traversal time begins to plateau; however, overtraining can lead to increased stalling and turning on the beam. Following experimental modulation, the testing phase begins, and data are recorded as "time to traverse." Usually, results are obtained by averaging at least two crossings in which the tested animal did not stop or require prodding.
Now that we've seen the experimental set-ups of commonly employed behavioral tests, let's look at some specific applications of these methods.
Aging is a normal biological process, one consequence of which is the degradation of the vestibular system as hair cells produce fewer cilia, and also begin to die. The result of this is loss of balance that can result in increased falls in the elderly. In this experiment, mice of varying ages went through a vestibular challenge in which they were spun in a rotator for 20 seconds and immediately after that asked to traverse a slanted beam. Researchers observed that older mice are more dramatically affected by vestibular challenge than the younger mice.
Rotarod testing is useful in studying gross motor deficits and fatigue resistance, making it ideal for studying a disease like muscular dystrophy. The hallmark of muscular dystrophy is muscle damage that ultimately results in deficits in mobility, coordination, and balance. In this experiment, researchers compared rotarod running times between wild type mice and mouse models of muscular dystrophy.
Parkinson's disease is characterized by the death of dopaminergic neurons in substantia nigra, and often presents with motor deficits and loss of coordination. In this experiment, a challenging beam test was performed. Comparing wild type mice to a genetically engineered Parkinson's model, it was observed that Parkinson's mice had increased errors per step and increased errors per beam width.
You've just watched JoVE's video on balance and coordination testing. This video discussed the neural correlates of balance and coordination, some prominent methods to test balance, and finally a few applications of these behavioral tests in neuroscience labs today. As always, thanks for watching!
View the full transcript and gain access to JoVE Science Education videos
Q1: What sensory systems work together to maintain balance and coordination?
Balance relies on three main sensory inputs: visual cues, proprioception (sense of body position), and the vestibular system in the inner ear. Proprioceptors in muscles and joints provide information about physical status, while the vestibular system contains semicircular canals with hair cells that detect head movement. These inputs travel to the brainstem and cerebellum, which coordinate them to fine-tune motor commands and increase muscle precision.
Q2: How does the vestibular system detect changes in head position and movement?
The vestibular system contains three semicircular canals filled with fluid called endolymph. Within each canal's ampulla is a cupula structure containing hair cells with cilia. When head movement causes endolymph to flow, it bends these cilia, which transmit signals to the vestibular nuclei in the brainstem. This mechanism allows the body to sense acceleration and orientation in space.
Q3: What is the rotarod test and how is it used to assess motor function?
The rotarod apparatus consists of a spinning dowel, multiple lanes for testing animals, and platforms for safe landing. Animals are trained to walk on an accelerating dowel over several sessions until their time to fall plateaus. After experimental intervention, testing measures time to fall as the dowel speed gradually increases. This test evaluates gross motor deficits and fatigue resistance in rodent models.
Q4: How does the balance beam test measure coordination differently than the rotarod?
The balance beam test uses a one-meter suspended beam where animals must traverse from a start point to an enclosed box. Motion sensors or video recorders measure traversal time. Training continues until average crossing time plateaus, but overtraining can increase stalling. Results are averaged from at least two crossings without stopping, providing a measure of fine motor control and balance on a narrow surface.
Q5: Why do older mice show greater balance deficits after vestibular challenges?
Aging degrades the vestibular system as hair cells produce fewer cilia and begin to die. In studies, older mice subjected to vestibular challenges, such as spinning in a rotator followed by beam traversal, showed more dramatic balance impairment than younger mice. This demonstrates how age-related vestibular decline directly impacts motor coordination and increases fall risk in elderly populations.
Q6: What motor deficits do Parkinson's disease models show in balance beam testing?
Parkinson's disease involves death of dopaminergic neurons in the substantia nigra, causing motor deficits and loss of coordination. Genetically engineered Parkinson's model mice showed increased errors per step and increased errors per beam width compared to wild-type mice during challenging beam tests. These findings highlight how dopaminergic loss impairs fine motor control and balance precision.
Q7: How do scientists use rodent models to study balance and coordination disorders?
Mice use similar sensory and neural systems for balance as humans, making them ideal for modeling physiological conditions. Researchers can induce conditions like muscular dystrophy or Parkinson's disease in mice, then test them using behavioral paradigms such as rotarod or balance beam. This approach allows scientists to observe how specific diseases affect motor coordination and validate potential treatments for movement disorders.
Chapters in this video
0:00
Overview
1:04
Neurophysiology of Balance and Coordination
3:12
The Rotarod
5:20
The Balance Beam
6:40
Applications
8:34
Summary
Videos from this collection: