Larry D Sanford

Publications (90) View all

• Article: Effects of stressor predictability on escape learning and sleep in mice.

  Mayumi Machida, Linghui Yang, Laurie L Wellman, Larry D Sanford
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  ABSTRACT: Controllable stress, modeled by escapable shock (ES), can produce significant alterations in post-stress sleep, including increased rapid eye movement (REM) sleep. Recent work has demonstrated that post-stress sleep may be influenced by stressor predictability, modeled by predictive auditory cues. In this study, we trained mice with ES, either signaled (SES) or unsignaled (UES) by auditory cues, and investigated the effects of predictability on escape learning and sleep associated with ES. Adult male BALB/cJ mice were implanted for recording electroencephalography and activity via telemetry. After the mice recovered from surgery, baseline sleep recordings were obtained. The mice were then randomly assigned to SES and UES conditions. Both groups had control over the duration of footshocks (0.5 mA; 5.0 sec maximum duration) by moving to the non-occupied chamber in a shuttlebox. SES mice were presented tones (90 dB, 2 kHz, 10 sec maximum duration) that started 5.0 sec prior to and co-terminated with footshocks. UES mice were presented identical tones that were not synchronized to shock presentation. ES training continued for 2 consecutive days (EST1 and EST2) with 20 footshock presentations (1 min inter-stimulus intervals). Seven days after EST2, the animals were re-exposed to the training chamber (context) alone for 30 min. Escape latency was used to determine successful or unsuccessful escape learning. Sleep was scored for 20 h for baseline and on each treatment day. Freezing in the training context was scored as a behavioral index of fear. Nine of 14 SES mice successfully learned escape (SESl), and 5 failed to learn escape (SESf). Compared with baseline, SESl mice, but not SESf mice, showed significantly increased post-shock REM. All UES mice learned escape and showed enhanced post-shock REM. Freezing and sleep did not differ among groups on the context re-exposure day. The results indicate that information available in a stressful situation can affect an animal's ability to learn an appropriate response and post-stress sleep. CITATION: Machida M; Yang L; Wellman LL; Sanford LD. Effects of stressor predictability on escape learning and sleep in mice. 2013;36(3):421-430.
  Sleep 01/2013; 36(3):421-30. · 5.05 Impact Factor
• Article: Basolateral amygdala and the regulation of fear-conditioned changes in sleep: role of corticotropin-releasing factor.

  Laurie L Wellman, Linghui Yang, Marta A Ambrozewicz, Mayumi Machida, Larry D Sanford
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  ABSTRACT: To determine whether corticotropin-releasing factor (CRF) in the basolateral amygdala (BLA) modulated sleep and fear-conditioned alterations in sleep. After 2 days of habituation to recording procedures, baseline sleep recordings were obtained. The animals were then habituated to the handling procedure necessary for microinjections over 2 consecutive days. In experiment 1, rats received microinjections of 0.5 μL antalarmin (1.61 or 4.82 mM), a CRF receptor 1 antagonist, or distilled water once a week for 3 wk. In experiment 2, rats received a microinjection of either antalarmin or vehicle prior to inescapable shock training (ST; 20 shocks; 0.8 mA, 0.5 sec; 1 min interstimulus interval). The animals were placed back in the context 7 days later for 30 min without shock (CR; context re-exposure). Sleep was recorded for 8 h after each manipulation. NA. Outbred Wistar rats. The rats were surgically implanted with electrodes for recording the electroencephalogram and electromyogram for determining arousal state and with bilateral guide cannulae directed at BLA. Antalarmin microinjected into BLA did not significantly alter sleep under undisturbed conditions. However, antalarmin microinjected bilaterally into BLA prior to ST blocked reductions in rapid eye movement sleep that ST normally produces. Further, the single microinjection prior to ST blocked the reduction in rapid eye movement typically seen after subsequent CR. Behavioral freezing, an indicator of fear memory, was not altered. CRF in BLA is involved in regulating stress-induced alterations in sleep and it plays a role in modulating how stressful memories influence sleep. CITATION: Wellman LL; Yang L; Ambrozewicz MA; Machida M; Sanford LD. Basolateral amygdala and the regulation of fear-conditioned changes in sleep: role of corticotropin-releasing factor. SLEEP 2013;36(4):471-480.
  Sleep 01/2013; 36(4):471-80. · 5.05 Impact Factor
• Source

  Available from: Laurie L Wellman

  Dataset: JNI 475110

  Christina D Steel, Woong-Ki Kim, Larry D Sanford, Laurie L Wellman, Sandra Burnett, Nico Van Rooijen, Richard P Ciavarra
• Article: Executive Function in Rats is Impaired by Low (20 cGy) Doses of 1 GeV/u (56)Fe Particles.

  György Lonart, Brian Parris, Angela M Johnson, Scott Miles, Larry D Sanford, Sylvia J Singletary, Richard A Britten
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  ABSTRACT: Exposure to galactic cosmic radiation is a potential health risk in long-term space travel and represents a significant risk to the central nervous system. The most harmful component of galactic cosmic radiation is the HZE [high mass, highly charged (Z), high energy] particles, e.g., (56)Fe particle. In previous ground-based experiments, exposure to doses of HZE-particle radiation that an astronaut will receive on a deep space mission (i.e., ∼20 cGy) resulted in pronounced deficits in hippocampus-dependent learning and memory in rodents. Neurocognitive tasks that are dependent upon other regions of the brain, such as the striatum, are also impaired after exposure to low HZE-particle doses. These data raise the possibility that neurocognitive tasks regulated by the prefrontal cortex could also be impaired after exposure to mission relevant HZE-particle doses, which may prevent astronauts from performing complex executive functions. To assess the effects of mission relevant (20 cGy) doses of 1 GeV/u (56)Fe particles on executive function, male Wistar rats received either sham treatment or were irradiated and tested 3 months later for their ability to perform attentional set shifting. Compared to the controls, rats that received 20 cGy of 1 GeV/u (56)Fe particles showed significant impairments in their ability to complete the attentional set-shifting test, with only 17% of irradiated rats completing all stages as opposed to 78% of the control rats. The majority of failures (60%) occurred at the first reversal stage, and half of the remaining animals failed at the extra-dimensional shift phase of the studies. The irradiated rats that managed to complete the tasks did so with approximately the same ease as did the control rats. These observations suggest that exposure to mission relevant doses of 1 GeV/u (56)Fe particles results in the loss of functionality in several regions of the cortex: medical prefrontal cortex, anterior cingulated cortex, posterior cingulated cortex and the basal forebrain. Our observation that 20 cGy of 1 GeV/u (56)Fe particles is sufficient to impair the ability of rats to conduct attentional set-shifting raises the possibility that astronauts on prolonged deep space exploratory missions could subsequently develop deficits in executive function.
  Radiation Research 08/2012; 178(4):289-94. · 2.68 Impact Factor
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  Available from: Laurie L Wellman

  Article: Effects of microinjections of Group II metabotropic glutamate agents into the amygdala on sleep.

  Enheng Dong, Laurie L Wellman, Linghui Yang, Larry D Sanford
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  ABSTRACT: Systemic administration of the Group II metabotropic glutamate (mGlu) receptor agonist, LY379268 (LY37), dose-dependently suppresses rapid eye movement sleep (REM) whereas systemic administration of the mGlu II receptor antagonist, LY341495 (LY34), increases arousal. Group II mGlu receptors are highly expressed in the amygdala, a brain region involved in the regulation of sleep and arousal. To determine whether the amygdala is involved in mediating the effects of Group II mGlu agents on sleep, we microinjected LY37 and LY34 into the basal amygdala (BA) and the central nucleus of the amygdala (CNA) and recorded sleep and wakefulness. Wistar rats were implanted with electrodes for recording sleep and with bilateral cannulae aimed into BA for drug administration. Different groups of rats received bilateral microinjections of LY37 into BA at two dosage ranges (3.2 mM, 5.3 mM or 10.7 mM or 0.1 nM, 2.0 nM or 10.0 nM) or one dosage range of LY34 (1.0 nM, 30.0 nM or 60.0 nM). Microinjections into CNA were conducted at one dosage range for LY37 (0.1 nM, 2.0 nM or 10.0 nM) and for LY34 (1.0 nM, 30.0 nM or 60.0 nM). All drugs or vehicle alone were administered in a counterbalanced order at 5-day intervals. Following microinjection, sleep was recorded for 20 h. Microinjection of LY37 into BA at both nM and mM concentrations significantly decreased REM without significantly altering NREM, total sleep or wakefulness. The high dosage of LY34 in BA significantly suppressed NREM and total sleep. Microinjections of LY37 or LY34 into CNA had no significant impact on sleep. We suggest that Group II mGlu receptors may influence specific cells in BA that control descending output (via the CNA or bed nucleus of the stria terminalis) that in turn regulates pontine REM generator regions.
  Brain research 03/2012; 1452:85-95. · 2.46 Impact Factor