Ashley and Andrew attended Neurotrauma 2024! Ashley presented her poster on the role of phagocytic receptors in controlling repair after CNS injury. It was a thought-provoking conference with fantastic friends and colleagues. We shared discussion, lunches, and happy hour around the Hilton Union Square in San Francisco.

The Fonken-Gaudet labs took a Saturday trip to Texas A&M and College Station to experience a riveting series of sessions exploring circadian biology. The annual Texas Society for Circadian Biology and Medicine provides a rich forum for learning about chronobiology and meeting other circadian researchers. Texas is so large and has so many research institutes that each of these “small” meetings has expertise that meets or exceeds that found in most countries! We had fun learning about diverse topics and biological systems linked by a shared passion for biological clocks. See you all next year!

Sydney Lee defended her Ph.D. dissertation today - congratulations, Sydney!

Sydney joined the lab in 2019 as a technician, then as the first G-lab graduate student in 2019. Sydney has been a productive and positive member of the lab, and is an excellent mentor for younger trainees.

Sydney’s dissertation is titled, “ Exploring pain- and anxiety-like behavioral disturbances after spinal cord injury in male and female mice.” Sydney published two excellent first-author primary research papers exploring pain- and anxiety-like behaviors in mice after spinal cord injury. A third primary research paper is published as a preprint, and is under review at an excellent journal - this manuscript newly unmasks robust sex differences in anxiety-like behavior in mice, with females exhibiting higher anxiety-like behavior.

Sydney’s rigorous work will have a long-lasting impact on the areas of spinal cord injury, chronic pain, anxiety, and sex as a biological variable. Sydney will stay on as a postdoc as she secures her next position. Congrats again, Sydney, and good luck!

Today was an exciting day at UT - faculty learned about their promotion cases! Andrew Gaudet (Psychology) and his collaborator Laura Fonken (Pharmacy) were both approved for promotion to Associate Professor with tenure! The Gaudet and Fonken labs celebrated on Friday afternoon near UT’s Turtle Pond and tower. What a beautiful day for celebrating. We appreciate all of the trainees, researchers, staff, and mentors who made this possible. Congrats to all who were promoted!

Our new paper has been accepted for publication at Experimental Neurology! Congrats to co-first authors Dr. John Aldrich and Ashley Scheinfeld, and the rest of our team. In this manuscript, we sought to determine whether dim light-at-night (dLAN) after spinal cord injury (SCI) alters locomotor recovery, pain- or mood-related behaviors, or neuroprotection.

Our new manuscript is available at Experimental Neurology; the article is accessible on BioRxiv; and its dataset is on Open Data Commons repository.

Our prior work established that SCI disrupts the circadian system, including glucocorticoid rhythms, core temperature and activity rhythms, and rhythms of clock and inflammatory gene RNA in the spinal cord and liver. Others revealed that clinically relevant environmental circadian disruptors – such as dLAN – can exacerbate secondary damage and recovery in neurological conditions, such as global ischemia.

In our manuscript, we hypothesized that dLAN initiated after SCI would worsen functional and anatomical deficits. Adult female and male mice were subjected to SCI (or sham surgery), then placed back in light-dark (LD) cycles or newly placed in dLAN (12 h light; 12 h dim 15 lux light). This was designed to mimic the hospital setting, which often has unnaturally high nighttime light levels.

Our results showed that dLAN had modest effects on behavioral outcomes. Locomotor recovery was assessed using the open-field Basso Mouse Scale (BMS). dLAN had little effect on locomotor recovery after SCI, except at the final timepoint, when SCI-dLAN mice had increased function compared to SCI-LD mice (Fig. 1a above). Lesion size and neuroprotection were not significantly different between SCI-LD compared to SCI-dLAN mice. Neuropathic pain-like behavior was assessed using the Hargreaves test (heat) and the von Frey test (mechanical). Whereas dLAN did not modulate sensitivity to heat (not shown), SCI-dLAN mice showed worsened mechanical hypersensitivity at 13 dpo only compared to SCI-LD mice (Fig. 1b). Mood-related behaviors were assessed using the sucrose preference test, open field test, and juvenile social exploration. dLAN had no significant effect on sucrose anhedonia or open field behavior (not shown). Interestingly, SCI-dLAN mice had decreased juvenile social exploration at 21 dpo compared to SCI-LD mice (Fig. 1c), suggestive of worsened anxiety- and/or depressive-like behavior.

Overall, our data suggest that dLAN has mixed effects on behavioral recovery after SCI - compared to SCI-LD mice, SCI-dLAN mice had slightly improved locomotor recovery at 28 dpo, worsened mechanical hypersensitivity at 13 dpo, and heightened anxiety-like behavior at 21 dpo. Future studies should explore whether SCI recovery is impaired by other clinically relevant circadian disruptors – e.g., LAN in a melatonin-expressing strain, sleep deprivation, or combining disruptors. Ultimately, studying circadian disruption after SCI in mice will help define whether improving circadian hygiene in acute clinical care could benefit SCI recovery.

Science and skis - the Winter Conference for Brain Research provides an ideal venue for discussing research and integrating those thoughts afterwards on the slopes. Networking opportunities occurred during seminars - but also in the lodge, on the ski lift, or at apres-ski. The Conference occurred in late January 2024 in Breckenridge, CO. Dr. Gaudet was invited to speak at a session on Immune-Sympathetic Effects of Spinal Cord Injury and presented a talk titled, “Circadian control of neuroinflammation after spinal cord injury.”

Texas meets Texas A&M - but without the rivalry. Dr. Gaudet and his lab members were invited to present at the Annual Winter Society for Neuroscience Symposium, hosted by the Texas A&M Institute for Neuroscience! Gaudet was honored to be the keynote speaker, and presented a seminar titled, “Neuroimmune regulation of biology and behavior.” Lab members John Aldrich, Sydney Lee, Ashley Scheinfeld, and Kalina Dusenbery presented posters. It was great to see our A&M friends, meet with faculty, and discuss lab life with graduate students. We enjoyed the hospitality and innovative science in College Station!

Kalina Dusenbery just joined the team as a Research Associate! Kalina completed her B.S. in Systems and Behavioral Neuroscience at the Ohio State University. Kalina is particularly excited to work on our chronobiology projects. We’re excited to see what you discover!

Our team, led by graduate student Sydney Lee, published a paper in Experimental Neurology addressing how spinal cord injury (SCI) affects the relative salience of anxiety vs. heat sensitivity (access pdf here also).

To explore the effects of SCI on mouse behaviors, we used our newly developed Thermal Increments Dark-Light (TIDAL) conflict test (Fig. 1) (for more details, see our related preprint). This test places mice in a two-chambered apparatus: one chamber remains dark but gradually heats to aversive temperatures, whereas the other chamber is illuminated and remains isothermic. If SCI caused strongly increased heat sensitivity, then mice would leave the dark, heating plate more quickly than control sham mice. Conversely, if SCI increased the salience of anxiety more than heat, then mice would persist on the dark plate longer despite increasing temperatures.

Our previous work showed that female mice exhibit increased preference for the dark, heating plate, suggesting that females exhibit increased salience of anxiety-related stimuli compared to males. Here, we again showed that females display increased anxiety-like behavior.

Interestingly, SCI in both females and males increased preference for the dark, heating plate compared to sham control mice (Fig. 2 below; Fig. 3 and 4 in the paper). This was not simply increased preference for warmth - SCI mice with both plates illuminated (thermal place preference, TPP) had reduced preference for the heated plate compared to mice on TIDAL. SCI increased dark-heated plate preference at all heated temperatures, from 39-44°C. Therefore, female and male mice at 7 d post-SCI displayed increased salience of anxiety.

A subset of mice were tested at 7 d post-operative (dpo) and re-tested at 21 dpo to establish whether anxiety-related differences persist, or whether differences are dampened and/or affected by learning (Fig. 5 and 6 in the paper). Our data showed differential effects in females and males. Females with SCI or sham surgery at 21 dpo both showed high initial dark plate preference, but decreased preference more quickly at higher temperatures (42-44°C). Males with SCI showed increased preference for the dark plate at 21 dpo compared to sham mice (a difference that was not apparent at 7 dpo), suggesting that male mice with SCI maintain higher anxiety-like behaviors than sham males.

Overall, we use our new TIDAL conflict test to reveal that SCI in mice drives previously underappreciated increases in anxiety-like behavior. Previous studies had suggested mice display minor anxiety-like behavior. Our data imply that placing an anxiety-driving stimulus in conflict with another stimulus - here, heat - can unmask underestimated anxiety-like behaviors. Testing using TIDAL revealed that both female and male mice with SCI exhibit increased anxiety-like behaviors at 7 dpo. Future studies could use TIDAL or other conflict tests after SCI to explore behaviors related to mood and anxiety. Ultimately, studying behaviors related to mood and anxiety after SCI could enhance our understanding of mechanisms and targets for improving mood-related therapies for humans afflicted with SCI or other neurologic conditions.

Dr. Gaudet’s first R01 was awarded today! The title of the grant is “Circadian control of neuroinflammation after spinal cord injury.” Gaudet is grateful for all of his collaborators and trainees who helped achieve this milestone. We’re delighted for the opportunity to explore how the circadian system regulates inflammation after spinal cord injury.

Dr. John Aldrich recently joined the Gaudet lab as a Research Scientist! Dr. Aldrich has a varied background - he has studied flies, eyes, chromatin, genes, the nervous system…the list goes on! He also has experience with RNA sequencing and various cellular and molecular techniques. Dr. Aldrich’s wealth of knowledge will help level up lab productivity and dynamics! Welcome.

The Gaudet lab published an exciting new paper in Journal of Neurotrauma titled, “Sex differences in pain: Spinal cord injury in female and male mice elicits behaviors related to neuropathic pain.”

Chronic pain afflicts 65% of individuals with spinal cord injury (SCI). Women are more susceptible to pain symptoms than men. Although previous preclinical studies have explored sex differences in SCI-elicited pain-like behaviors, it remains understudied how SCI-driven pain behaviors develop over time and differ between the sexes. Here, we hypothesized that moderate force T9 contusion SCI in mice would cause neuropathic pain-like behaviors, and that these would be exacerbated in females compared to males.

First, we explored the effects of two different SCI forces on pain-like behaviors in female mice (Fig. 1). Both 60 and 75 kDyn SCI elicited mechanical allodynia (von Frey test) and heat hyperalgesia (Hargreaves test). The more severe 75 kDyn SCI caused excessive sensorimotor deficits at 7 d post-operative (dpo) that confounded sensory testing, so we used the less-severe 60 kDyn force for subsequent studies.

Next, we compared female and male mice with SCI regarding locomotor recovery and pain-like behavior (Fig. 2). Using the Basso Mouse Scale for locomotor recovery, females recovered slightly slower than males. For mechanical sensitivity, SCI caused increased hypersensitivity in mice of both sexes across all times tested (weekly from 6-27 dpo), and there was no substantial difference between females and males (Fig. 2 below; and Fig. 2-4 in the paper). However, females did show increased hypersensitivity at 27 dpo (Fig. 3 below; and Fig. 4 in the paper). For heat sensitivity, SCI again increased heat hypersensitivity at all times tested. Females with SCI exhibited increased hypersensitivity compared to males (Fig. 2 and Fig. 4 below; and Fig. 2, 3, and 5 in the paper).

One strength of our study was the uniquely large size of our dataset. We have completed several experiments using age-matched mice of both sexes, so here we compiled a rigorous and comprehensive analysis of pain-like behavior in female and male mice. One limitation of our study is we assessed pain-like behaviors using only evoked tests, which may have limited relevance for chronic pain related to dull, ongoing sensations or spontaneous pain. Separately, we also created a test that attempted to unveil affective-related pain-like behaviors, though instead this revealed increased anxiety-like symptoms. Thus, it is challenging to develop effective tests for spontaneous or affective pain-like behavior in mice with SCI, particularly given the confounding combination of motor and sensory deficits. Others are also working on this challenge; e.g., Angelo Lepore’s group has used the grimace scale in mice to measure spontaneous pain-like behavior after SCI.

Overall, our data suggest that moderate T9 contusion SCI in mice reliably causes mechanical and heat hypersensitivity, and that females with SCI exhibit increased heat hypersensitivity compared to males. Sex differences in pain-like behavior may relate to sex-specific underlying mechanisms. Future research should continue integrating sensory testing and both sexes. Ultimately, these studies will help unravel the relationship between sex/gender and neuropathic pain and to develop new therapies to benefit individuals with SCI.

How does brain physiology shift in response to aging?

How does the CNS interact with the neuroimmune system, and how does this change with age?

How are these changes beneficial and detrimental?

These are some of the questions addressed by Andrew and long-time collaborator Laura Fonken in their latest review paper, titled “Neuroimmunology of healthy brain aging,” published in Current Opinion in Neurobiology.

Key points addressed in the review: Aging progressively disrupts homeostatic systems, including neuroimmunity. Neuroimmune responses in the aged brain are sensitized, and include impaired phagocytosis. With age, key neuroimmune-related cells - including microglia, astrocytes, and T cells - develop primed or pro-inflammatory phenotypes. In addition, the aged glymphatic system enables pathological accumulation of danger signals and cytokines. Age-related neuroimmune hyperreactivity has behavioral consequences - e.g., age-related neuroimmune activity predisposes to cognitive decline.

65% of individuals with spinal cord injury (SCI) experience chronic pain. Further, chronic pain afflicts females more frequently, and can act on females vs. males via distinct cellular mechanisms. Unfortunately, we still lack effective treatments for chronic pain and do not fully understand mechanisms underlying sex differences in pain. In our new preprint, we reveal that female and male mice with SCI exhibit neuropathic pain symptoms. Further, females have amplified pain symptoms compared to males. Our thorough study illuminates an effective SCI model and pain tests for elucidating SCI pain-related mechanisms. Future studies should use complementary evoked and affective-related pain tests to gain a broad perspective on SCI-driven pain. We also had fun discussing the implications of this study, relating to sex differences and other future directions.

Sydney Lee, Emily Greenough, and Paul Oancea from the lab led the study.

Are you looking to level up your research experience? Are you interested in neuroscience, and a vibrant research team and environment? Check us out!

The Gaudet lab at the University of Texas at Austin is hiring a Research Technician. Our research focus is using rodent models to improve inflammation in the central nervous system. We use molecular, cellular, and behavioral techniques. Our main model of interest is spinal cord injury, and we also study affective behaviors such as those related to anxiety, locomotion, and sensation.

Salary is flexible depending on experience.

Austin is a great place to live - lively neighborhoods, great music, outdoor fun, happy people. UT-Austin is a remarkable place for learning and growth. And in the Gaudet Lab, we aim to support your success by enabling you to use your own expertise and to learn more about new techniques and how to science. Let’s publish together!

All of these benefits combine in a nicely sized lab (not too big and not too small!) with a positive and productive team of researchers.

Interested in grad school? We’re accepting applications this Fall! See details on graduate school applications to UT’s Departments of Psychology or Neuroscience here.

Gaudet was delighted this week to visit Drexel College of Medicine in Philadelphia! Drexel has so many productive and interesting people - lots of interesting questions and ideas were discussed.

It was great having lunch with the trainees. It was my first time having a double-patty veggie burger, and the weather was perfect for the visit.

Thanks for the invitation, Megan Detloff!

We published a new preprint: “Anxiety-like behaviors in mice unmasked: Revealing sex differences in anxiety using a novel light-heat conflict test.” We have also submitted the manuscript for publication. The study was led by graduate student Sydney Lee. Thanks also to contributors Emily Greenough, Paul Oancea, and Laura Fonken.

Anxiety is twice as prevalent in women than men - yet tests for anxiety in rodents fail to consistently reveal sex differences. New preclinical approaches are required to unmask sex differences in anxiety.

Here, we reveal a new heat-light conflict test - the Thermal Increments Dark-Light (TIDAL) conflict test. In TIDAL, female (vs. male) mice exhibit strongly amplified anxiety behavior, recapitulating gender differences in human anxiety

The TIDAL test apparatus consists of two heat-controlled plates. One plate is illuminated and maintained at a "comfy" temperature. The other plate is dark - but its temperature increases incrementally to aversive temperatures..

Rodents can move freely between the plates. We found that females persist on the heated, dark plate to higher temperatures than males.

Thus, our novel TIDAL conflict test reveals robust anxiety behavior in females. Future studies should integrate TIDAL or other conflict tests to identify mechanisms and treatments for anxiety.

Dr. Gaudet and his lab have been awarded a grant from Mission Connect, a program of the TIRR Foundation! Mission Connect is a group that connects and funds spinal cord injury research in Texas. The group holds monthly meetings, and organizes a top-notch research meeting in Houston every November.

Gaudet’s grant will explore the role of neuroinflammation and phagocytosis after spinal cord injury. The proposal combines complementary transgenic and pharmacologic approaches. We are excited to proceed with this study, with an aim to identify novel neuroprotective therapies that improve SCI outcomes.