7 Things Every Teacher Should Know about the Physiological Impact of Trauma - Brookes Blog

7 Things Every Teacher Should Know about the Physiological Impact of Trauma

November 23, 2021

During the ongoing pandemic (and beyond), addressing the effects of trauma will be essential to students’ social-emotional well-being and readiness for learning. Understanding the impact of trauma on the brain and body is an important step—and this week, we’re featuring a valuable primer from Dyane Carrere, an expert on trauma-informed teaching and the author of The Re-Set Process: Trauma-Informed Behavior Strategies . Adapted from her recent coffee chat, this post takes you through 7 types of physiological differences you might see as a result of trauma, and gives you some ready-to-use strategies to provide necessary support to students.

Cognitive functioning differences

During times of stress, our emotions get bigger and our thinking gets smaller. Cortisol, the primary stress hormone, slows movement of a message from one neuron to the next in the brain, meaning that we tend to think slower during times of stress and trauma. What does this look like in the classroom? You might notice students who seem “oversensitive” and unfocused, and struggle to pick up content you present. All of these qualities can be manifestations of stress in the brain.

Here are a few ways to support kids with stress-related cognitive functioning differences:

Vision and auditory differences

Sensory systems also shift during times of high stress. Visual systems come more “online” and auditory systems retreat, so we see more and hear less. You might see this manifested in students who seem to have trouble paying attention or are focusing on something other than your voice.

In cases like these, talking to students may not be the best way of getting and maintaining their attention. To support students more effectively, try these methods instead:

Hippocampus and prefrontal cortex differences

When cortisol is in the brain, it doesn’t allow for cell reproduction in the hippocampus and prefrontal cortex—meaning that children who have experienced a lot of trauma over time may have a smaller hippocampus and a less connected prefrontal cortex. Since the hippocampus controls working memory, you might notice students who look distracted, have a hard time following multi-step directions, or even fall asleep or “shut down” in class. And prefrontal cortex differences may produce obvious difficulties with executive skills such as task initiation, organization, and time management.

Here are some supports you can try:

Dorsolateral prefrontal cortex differences

The dorsolateral prefrontal cortex is the specific part of our brain responsible for understanding time and sequence. During times of stress and trauma, this part may not be as “wired in”—meaning that students may struggle with getting homework or classwork done on time, or with relating a story or event in sequence (details may be fragmented and scattered).

To support students who need help with time and sequencing:

Posterior cingulate differences

This part of the brain, which is responsible for telling us where our body is in space, also goes offline during times of stress. What does this look like in the classroom? You might see a student stretching out across a work surface and invading their classmates’ space, a student needing to touch peers or objects as they move across the room, or a student spreading out on the floor to seek grounding.

To offer support, try these strategies:

Vasopressin and oxytocin differences

Vasopressin and oxytocin are chemicals that allow us to develop calming pathways to the brain. When students don’t get enough of these chemicals, you may notice that they have trouble calming themselves and settling down after an activity like recess or lunch.

To help build those critical calming pathways:

Neurological system organization differences

A student’s neurological system may be less organized if they’ve had pervasive trauma. Students with stress-related neurological system organization differences may touch people harder, have food on their faces because they’re less attuned, or struggle with fine motor tasks like buttoning a coat or turning pages.

Support your students with strategies like these:

In addition to these specific supports, Dyane Carrere also recommends that teachers “assume can’t, not won’t.” When you operate from the assumption that students are trying their best, and that kids are experiencing challenges instead of being defiant, it will make you a more compassionate educator and better able to help every child succeed.

Use the strategies in this article to provide critical supports when your students struggle with the physiological impacts of trauma. And for a specific, neuroscience-based approach to improving behavioral success in your classroom, be sure to check out The Re-Set Process.

The Re-Set Process

Trauma-Informed Behavior Strategies

By Dyane Lewis Carrere, M.Ed., with Wynne Kinder, M.Ed.

Educators need a clear and consistent trauma-informed process to help their students re-regulate and return to learning—and that’s what they’ll find in this reader-friendly guide to the Re-Set Process, a neuroscience-based approach to improving behavioral success in children from Grades K–8. Includes a wide array of practical strategies for meeting trauma-based needs and a complete package of more than 30 online downloads to help you implement the Re-Set Process, including planning forms, blank templates, activity sheets, and a book study guide.