The authors would like to thank Hannah Zamore, Emily Saks, and Josh Searle for their help in establishing this operant strategy shifting paradigm in the Grafe lab. They would also like to thank Kevin Snyder for his help with the MATLAB code for analysis.

All procedures in this study were approved by the Institutional Animal Care and Use Committee (IACUC) at Bryn Mawr College.&#160;Obtain IACUC or otherwise applicable regulatory approval before ordering laboratory animals and beginning experimentation.
1. Animal preparation
<ol>
	<li>Acquire male and female adult Sprague Dawley rats. 
	NOTE: The rats can be delivered before 65 days of age, but do not begin procedures until after this point to ensure that both males and females are fully ...

The protocol demonstrates how to measure the effects of stress on cognitive function. Specifically, a modified operant strategy shifting paradigm is used in rodents, which measures cognitive flexibility (analogous to the Wisconsin Card Sorting Task in humans)1. Cognitive flexibility denotes the ability to adapt cognitive processing strategies to face new conditions in the environment, and it is crucial for normal daily functioning2. As human studies on cognitive flexibility...

In humans, stressful life events can impair cognitive function (i.e, cognitive flexibility1), which denotes the ability to adapt cognitive processing strategies to face new conditions in the environment2. Impairment in cognition precipitates and exacerbates many psychiatric disorders, such as Post Traumatic Stress Disorder (PTSD) and Major Depressive Disorder (MDD)3,4. These disorders are twice as prevalent in females5,6,7,8, yet the biological basis for this disparity remains unknown. Aspects of executive functioning in humans can be assessed using the Wisconsin Card Sorting Task, a demonstration of cognitive flexibility2. Performance in this task is impaired in patients with PTSD9 and MDD10, but the neural basis of this change can only be examined by brain imaging11.
Advances in understanding how stress affects the brain have been made through the use of animal models, particularly rodents. As cognitive flexibility is affected in stress-related diseases, it is an exceptionally relevant phenotype to examine in rodents. To date, most stress neurobiology literature has used an alternative cognitive flexibility paradigm (sometimes referred to as the digging task)12,13,14,15. While this task has been extensively vetted, it requires more time and effort by the experimenter to train rodents. Adapted and described here is a well-established automated set-shifting protocol16 to assess cognitive flexibility in male and female Sprague Dawley rats using various stress models17,18. The procedure requires minimal oversight by the experimenter and allows multiple rats to be tested simultaneously. In addition, unlike other versions of this automated task19, the adaptation of this paradigm only requires 3 days of training and includes an efficient programmed data analysis.
Whether stress enhances or impairs cognitive function depends on the type, intensity, and duration of the stressor, as well as the timing of the stressor in relation to learning or executing a cognitive task20,21. Thus, the protocol incorporates stress procedures both before and after the operant training. It also examines representative results from stress studies. In addition, the brain regions underlying particular aspects of set-shifting have been well-established2,16,22; thus, the report also describes how to target and assess particular brain regions during or after the stress and strategy shifting procedures.
There has been limited research on directly examining sex differences in cognitive flexibility18,23. &#160;The protocol describes how to 1) incorporate both male and female rats into the experimental paradigm, then 2) track estrous cycles before and during the procedures in freely cycling females. Prior studies have indicated that stress before operant training can lead to sex-specific deficits in cognitive flexibility in rats17. Particularly, female rats exhibit disruptions in cognitive flexibility after stress, whereas cognitive flexibility improves in male rats after stress17. Interestingly, a major hallmark of stress-related psychiatric disorders, which have a sex-biased incidence in humans, is cognitive inflexibility. These results suggest that females may be more vulnerable to this type of cognitive impairment than males. The use of these techniques in animal models will shed light on the effects of stress on the brain and how it impairs cognition in psychiatric disorders in humans.

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			<td height="21" style="height:21px;width:335px;">C-fos mouse monoclonal primary antibody</td>
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			<td height="21" style="height:21px;width:335px;">MatLab</td>
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			<td>Software; code to help analyze set shifting data, available upon request.</td>
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			<td>Many different parts for the chamber set up and software to work with it; we also wrote a separate code for set shifting, available upon request.</td>
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			<td style="width:201px;">Bryn Mawr College</td>
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assessment of stress effects on cognitive flexibility using an operant strategy shifting paradigm

Stress affects cognitive function. Whether stress enhances or impairs cognitive function depends on several factors, including the 1) type, intensity, and duration of the stressor; 2) type of cognitive function under study; and 3) timing of the stressor in relation to learning or executing the cognitive task. Furthermore, sex differences among the effects of stress on cognitive function have been widely documented. Described here is an adaptation of an automated operant strategy shifting paradigm to assess how variations in stress affect cognitive flexibility in male and female Sprague Dawley rats. Specifically, restraint stress is used before or after training in this operant-based task to examine how stress affects cognitive performance in both sexes. Particular brain areas associated with each task in this automated paradigm have been well-established (i.e., the medial prefrontal cortex and orbitofrontal cortex). This allows for targeted manipulations during the experiment or the assessment of particular genes and proteins in these regions upon completion of the paradigm. This paradigm also allows for the detection of different types of performance errors that occur after stress, each of which has defined neural substrates. Also identified are distinct sex differences in perseverative errors after a repeated restraint stress paradigm. The use of these techniques in a preclinical model may reveal how stress affects the brain and impairs cognition in psychiatric disorders, such as post-traumatic stress disorder (PTSD) and major depressive disorder (MDD), which display marked sex differences in prevalence.

The adapted automated operant strategy shifting paradigm outlined above was used to determine if repeated restraint stress affects cognition in male and female Sprague Dawley rats. Representative behavioral data are described in Figure 2 below. In short, control and repeatedly restrained rats performed this operant strategy shifting test, which consisted of a series of tasks: side discrimination, side reversal, and light discrimination.
Trials to criterion for eac...

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Assessment of Stress Effects on Cognitive Flexibility using an Operant Strategy Shifting Paradigm

Stressful life events impair cognitive function, increasing the risk of psychiatric disorders. This protocol illustrates how stress affects cognitive flexibility using an automated operant strategy shifting paradigm in male and female Sprague Dawley rats. Specific brain areas underlying particular behaviors are discussed, and translational relevance of results are explored.

Stress affects cognitive function. Whether stress enhances or impairs cognitive function depends on several factors, including the 1) type, intensity, and ...

This protocol integrates an automated opera and strategy shifting task with a flexible stress paradigm, enabling experimenters to efficiently assay the impact of stress on cognition. The advantages of this technique or its efficiency with the automation of the cognitive task and its flexibility because it can be paired with many other stress paradigms. This method provides insight to the interplay between the stress and cognition.It could also be extended to assess other variables such as the effect of drug exposure on cognition. Visual demonstration ensures that newcomers to this technique know how to properly test the function of the operant chambers before running subjects to avoid any glitches. Use operant chambers for behavior training and testing.Ensure that the chambers contain at least two retractable levers with two stimulus lights above. A house light and a dispenser for reinforcement of these tasks. Make sure that the levers are on either side of the central reinforcement delivery area with one stimulus light above each lever.Then use the house light to eliminate the chamber without interfering with detection of the light stimulus. Use dustless food pellets for reinforcement in food restricted rats. Making sure that the pellets are not high in sucrose or fat, control the presentation of stimuli, lever operation and data collection with software capable of operating the chamber.Fill the bottom tray of each operant box with fresh bedding to collect waste. After each session dump each tray, clean it with alcohol wipes and add fresh bedding before placing a new animal in the chamber. Decide whether the stress procedure should be performed before, during or after a training on the operant strategy shifting paradigm and execute the stress procedure at the same time daily with respect to operant training.In a separate room that is neither the colony room or the strategy shifting paradigm room, place the rat in a broom style transparent restraint tube and seal the opening. Taking care not to pinch the limbs or tail stagger the stress procedure for subjects depending on how many operant chambers are available. Before placing the rat in the chamber, ensure that there are enough food pellets in the dispenser and that the operant boxes are properly functioning.Do this by loading and initiating a program in an empty chamber and manually testing that the correct lever delivers one reward per lever press. Before placing the rat in the box for the first day training, manually set one food pellet reward on the correct lever as designated upon loading the training procedure within each chamber. Train the rat using a fixed ratio schedule such that each correct lever press is rewarded with one reinforcement.Counterbalance the correct lever per day across subjects or experimental conditions. Allow the rat to press the lever until it reaches the criterion by pressing the correct lever at 50 times which usually takes between 30 and 45 minutes. On the following day, force the rat to perform this task on the opposite lever using the same program and designating the opposite lever as the correct one.On the test day, place the rat in the operant chamber following stress procedures and test it in side discrimination, side reversal and light discrimination tasks serially. Ensure that the light discrimination task only illuminates the light above the correct lever. For the side discrimination task, reward the rat for pressing the lever on its least preferred side as determined from the third day of training.Regardless of the light cue, the task ends upon pressing the correct lever eight times consecutively. For the side reversal test, use the side discrimination program again but designate the opposite lever to be the correct one. The rat should be rewarded for pressing this lever regardless of the light cue.It must press the lever eight times consecutively to end the task. To perform the light discrimination task, reward the rat for pressing the lever with the light illuminated above. Again, each operant testing is complete upon pressing the correct lever eight times consecutively.This adapted automated operant strategy shifting paradigm was used to determine if repeated restraint stress affects cognition in male and female Sprague Dawley rats. A reduced number of trials or criterion indicated a better performance on each task. Following acute restraint, males completed the side reversal task insignificantly fewer trials than unstressed control males.Conversely, stressed females required a greater number of trials to complete the task. The total number of errors made for each attention task is shown here consistent with the number of trials to criterion. Stressed males made significantly fewer errors than control males in the side reversal task.Whereas stressed females made more errors. Furthermore, in the light discrimination task, females also made significantly more errors. In some, these data suggest that repeated stress improves cognitive performance in males but impairs cognitive performance in females.Total errors were further categorized into perseverative or regressive errors. Stressed males made fewer perseverative errors in the side reversal task than control males. While stressed females made a greater number of perseverative errors than control females in both the side reversal and light discrimination tasks.The brain areas underlying the side reversal task were examined to determine whether they displayed a similar sex differences in neural activity. Stress induced a significant increase to neuronal activation in the orbital frontal cortex of males compared to controls. However, the opposite was observed in females.When attempting this protocol pay attention to which subject is in which task of the strategy shifting paradigm. After finishing that task, manually ensure that it moves to the next task with correct settings. Along with this procedure, experimenters can perform other behavioral studies on the effects of restraint or proceed directly to perfusion and immunohisticchemical techniques to determine which brain regions were important in strategy shifting.In addition to increasing the efficiency and throughput of the paradigm, this technique allows us to differentiate types of errors made by subjects into perseverative, regressive, and random errors.

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Assessment of Stress Effects on Cognitive Flexibility using an Operant Strategy Shifting Paradigm

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