Summary: Dogs with anxiety have stronger neural connections between the amygdala and other areas of the anxiety network in the brain compared to less anxious dogs.
Researchers at Ghent University in Belgium report abnormalities in functional neural networks of dogs diagnosed with anxiety.
Led by Yangfeng Xu (Ghent Experimental Psychiatry Lab, GHEP; ORSAMI), and Emma Christiaen (Medical Image and Signal Processing, MEDISIP), the study shows that compared with healthy dogs, those with anxiety exhibit stronger connections between the amygdala and other regions of the anxiety network.
Published in PLOS ONE on March 15, the findings might also help reveal how functional connections between anxiety-related regions of the brain are altered in cases of human anxiety disorders.
Animal models of anxiety are an important tool for studying anxiety disorders, and results can benefit both veterinary and human medicine. However, the many different aspects of anxiety cannot all be studied effectively in the same animal model.
While rodents are often studied, this new study takes advantage of the larger brains and bigger cortex found in dogs to characterize neural networks associated with anxiety. 25 healthy and 13 anxious dogs were volunteered by their owners and examined via non-invasive functional MRI (fMRI).
The dogs were treated in accordance with all necessary welfare guidelines, ensuring that they suffered no negative consequences of the study. The researchers studied the resting-state of dogs with and without anxiety, comparing network metrics and connectivity between groups, and determining their associations with anxiety symptoms.
Resting-state fMRI indicated that functional connections between the amygdala and other parts of the anxiety circuit, particularly the hippocampus, were stronger than normal in anxious dogs.
Within the anxiety circuit, network metrics including global and local efficiency were higher in the amygdala of anxious dogs. Dogs which exhibited fear and anxiety towards strangers, as well as excitability, were more likely to have brains showing abnormal network metrics in the amygdala.
The researchers believe their findings show that resting-state fMRI is a good tool for studying dog-models of anxiety, and that future studies like this could increase our understanding of how anxiety-related circuitry in the brain is altered in anxiety-disordered animals, and possibly even humans with the condition.
The authors add, “In this manuscript, we constructed functional brain networks using graph theory metrics to compare the differences between anxious and healthy dog groups.
“Our findings could provide more insight into the topological organization of the functional brain connectome in anxiety disorder, thus lead to a better understanding of the pathophysiological mechanisms and illness course of anxiety in both animals and humans and help the development of more personalized and effective therapies.”
About this anxiety and animal psychology research news
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Original Research: Open access.
“Network analysis reveals abnormal functional brain circuitry in anxious dogs” by Yangfeng Xu et al. PLOS ONE
Network analysis reveals abnormal functional brain circuitry in anxious dogs
Anxiety is a common disease within human psychiatric disorders and has also been described as a frequently neuropsychiatric problem in dogs. Human neuroimaging studies showed abnormal functional brain networks might be involved in anxiety.
In this study, we expected similar changes in network topology are also present in dogs. We performed resting-state functional MRI on 25 healthy dogs and 13 patients.
The generic Canine Behavioral Assessment & Research Questionnaire was used to evaluate anxiety symptoms. We constructed functional brain networks and used graph theory to compare the differences between two groups. No significant differences in global network topology were found.
However, focusing on the anxiety circuit, global efficiency and local efficiency were significantly higher, and characteristic path length was significantly lower in the amygdala in patients.
We detected higher connectivity between amygdala-hippocampus, amygdala-mesencephalon, amygdala-thalamus, frontal lobe-hippocampus, frontal lobe-thalamus, and hippocampus-thalamus, all part of the anxiety circuit. Moreover, correlations between network metrics and anxiety symptoms were significant.
Altered network measures in the amygdala were correlated with stranger-directed fear and excitability; altered degree in the hippocampus was related to attachment/attention seeking, trainability, and touch sensitivity; abnormal frontal lobe function was related to chasing and familiar dog aggression; attachment/attention seeking was correlated with functional connectivity between amygdala-hippocampus and amygdala-thalamus; familiar dog aggression was related to global network topology change.
These findings may shed light on the aberrant topological organization of functional brain networks underlying anxiety in dogs.