Cognitive processes—the intricate mental functions that enable us to perceive, reason, remember, and learn—are fundamental to brain health and mental wellbeing.
These processes are central to how we interact with the world, solve problems, make decisions, and navigate the complexities of daily life. And cognition changes throughout a person’s life, such as during old age.
According to one study, up to 70% of aging individuals experience decline in processes that may affect processing speed and memory, as well as impact their quality of life and independence. Additionally, it’s estimated that over one in five adults in the U.S. experience mental illness, which can in some cases lead to cognitive impairments.
By understanding cognitive processes, healthcare providers can identify when a patient experiences changes in function that fall outside of normal expectations (e.g. age-related cognitive decline) and may be early indicators of cognitive decline, disorders, or mental health issues.
Read on to learn about the components of cognitive processes, examples, and how they impact daily life. Use this article to help guide conversations with patients as you measure cognition.
Cognitive processing relates to the mental activities associated with thinking, learning, memory, processing speed, and executive function.
Here are some important components of cognition:
Cognitive processing speed, which crucially affects how quickly we can complete cognitive tasks, tends to change over a person's life with evidence suggesting a natural decline with age. However, individuals who engage in certain interventions (such as exercise, socializing, or nutrition) may be able to slow cognitive decline in some preventable cases.
To detect and identify potential decline in cognitive processing, healthcare professionals can use cognitive assessments as valuable tools within their clinical practice. These assessments are commonly used to:
There are many benefits to healthcare providers capturing a baseline of a patient’s cognitive abilities (such as memory, recall, attention span, problem-solving skills, and processing speed).
Conducting routine cognitive assessments lets a healthcare provider identify important changes quickly, detect potential MCI earlier, and develop personalized care strategies that can potentially slow the progression of cognitive decline and improve an individual's quality of life.
Cognitive processing is the underlying mechanism for acquiring, refining, and using cognitive skills. For example, when an individual engages in a problem-solving task, cognitive processing takes place by enabling them to perceive information, apply reasoning, and retrieve relevant knowledge from memory.
Our cognitive skills, such as problem-solving, are also linked to areas of the brain. The activation of these various brain regions have been observed during brain imaging research.
In a landmark study published in Neuron, it was found that performance on the Creyos cognitive battery tends to cluster into three cognitive domains—reasoning, short-term memory, and verbal ability—and each domain recruited distinct (but interconnected) brain networks.
In addition to these three domains, attention or concentration enables us to sustain focus on specific tasks.
Let’s examine the specific brain regions involved in cognitive processes.
Understanding these neural pathways is essential for accurately assessing and treating disorders related to cognitive function. We will explore the activation patterns within the brain that correspond to certain cognitive processes assessed by different cognitive tasks, providing a clearer picture of the biological underpinnings of cognition.
Attention is the gatekeeper of our cognitive processes, determining what information we focus on and what we ignore. It involves a complex network of brain regions: the dorsolateral region of the right prefrontal cortex, the left inferior frontal gyrus, and the dorsal striatum, according to research compiled in the Brain Regions Guide.
Coupled with attention, response inhibition is a crucial executive function that enables us to suppress irrelevant stimuli or behaviors. The prefrontal cortex, the left inferior frontal gyrus, and the dorsal striatum largely manage this mechanism.
Attention and response inhibition can be tested using Creyos' Double Trouble test, which requires sustained focused attention.
Reasoning is a complex cognitive function that encompasses several sub-processes, including spatial processing, planning, and problem-solving. Spatial processing is deeply connected to the frontoparietal network, particularly the intraparietal sulcus of both hemispheres.
Visuospatial processing can be tested using Creyos' Polygons task, which requires patients to interpret visual information and detect subtle differences between shapes.
Planning is another facet of reasoning. Early imaging studies found that the mid-dorsolateral frontal cortex was activated in various versions of the Spatial Planning task. The caudate nucleus and the thalamus were involved only in more difficult puzzles. Multiple brain regions are engaged in problem-solving, including the dorsolateral prefrontal cortex (DLPFC) and inferior frontal gyrus (IFG), according to a systematic review of the subject.
Memory is a multifaceted cognitive function that encompasses several types, each relying on distinct brain regions. Working memory, for instance, engages the prefrontal, premotor, and posterior parietal cortex. The mid-dorsolateral prefrontal cortex, in particular, plays a role in working memory regardless of whether or not there is a spatial component, as outlined by Owen et al.
Working memory can be tested using Creyos' Number Ladder test, which requires storing numbers and their locations and then translating that memory into a series of movements in space.
Episodic memory primarily activates the left dorsolateral prefrontal cortex and the ventral and anterior left prefrontal cortex regions. It can be assessed using the Paired Associates task, which asks patients to remember which objects they previously saw along with the locations in which they were seen.
Spatial short-term memory involves the right mid-ventrolateral area and the parieto-occipital regions. Visuospatial working memory involves the prefrontal cortex, the mid-dorsolateral prefrontal cortex, the premotor cortex, and the posterior parietal cortex.
Verbal reasoning and language processing primarily activate the frontal operculum, the posterior temporal lobe, the superior parietal lobe, the dorsal prefrontal cortex, and the ventral prefrontal cortex.
The Grammatical Reasoning test requires individuals to judge the accuracy of the relationship between a statement and an object on the screen, primarily assessing verbal reasoning ability.
Verbal short-term memory, on the other hand, engages primarily the right hemisphere of the mid-ventrolateral prefrontal cortex. Digit Span, a straightforward memorization task, can test these cognitive processes.
Other cognitive processes like learning, executive function, and creativity also activate various parts of the brain. When we learn something new, our brain activates the hippocampus and the prefrontal cortex.
Executive function, a set of cognitive skills that include working memory, flexible thinking, and self-control, primarily involves the frontal lobes, particularly the prefrontal cortex, which orchestrates thoughts and actions.
Creativity, often considered the pinnacle of cognitive functions, lights up the brain's default mode network (DMN), which includes areas such as the medial prefrontal cortex, the posterior cingulate cortex, and the temporo-parietal junction. This network is most active when we're engaged in tasks involving imagination, such as daydreaming or brainstorming, suggesting that creativity arises from a complex interplay of multiple cognitive processes and brain regions. Research supports the role of the DMN in creative thinking and complex problem-solving.
To better understand the processes involved, let’s consider some practical examples.
Suppose an individual has visited a new city and is trying to remember the route from their hotel to a popular tourist spot. Here, spatial memory and sensory input come into play, allowing them to recall the directions.
Similarly, several cognitive processes are at work when reading a novel. For instance:
Dealing with a traumatic event or daily stressors also involves multiple cognitive functions:
Advancements in cognitive psychology and healthcare technology have made it possible to measure changes in cognitive function. Creyos, a cognitive healthcare solution, enables healthcare providers to assess changes in cognitive performance and address any concerns patients might have when cognitive changes impact their everyday lives.
Creyos streamlines care with comprehensive, easy-to-administer assessments for healthcare providers and researchers. This allows clinicians to:
For instance, determining the right time to return to work is critical when an individual sustains an injury, especially one potentially affecting cognitive function:
An occupational therapist with Assess Group uses a range of Creyos Health cognitive tests to evaluate the patient's speed and accuracy of cognitive processing, their ability to retain and manipulate information, and their capacity for complex problem-solving. These tasks were designed to simulate work-related cognitive demands, providing a realistic gauge of the patient's readiness to resume professional duties.
Understanding cognitive processes is key for healthcare providers as it directly influences patient care and outcomes. These processes enable us to interpret complex information, adjust to new or changing environments, and execute sophisticated tasks. Moreover, they are integral to our capacity to learn, communicate effectively, and make informed decisions.
Healthcare professionals benefit from a deep understanding of cognitive operations—they can connect the information from precise cognitive assessments back to these skills and use this knowledge in the development of targeted interventions.
Creyos offers a comprehensive suite of tools for healthcare providers to:
This post was edited by Mike Battista, Director of Science and Research at Creyos (formerly Cambridge Brain Sciences).