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Resumo

Condicionamento de rastreamento eyeblink clássico (ECC) foi utilizado para avaliar aprendizagem associativa de hipocampo-dependente em ratos adultos que foram administrados uma alta concentração (11,9% v/v) de álcool durante o desenvolvimento cerebral neonatal precoce. Em geral, procedimentos ECC são som ferramentas de diagnóstico para a detecção de disfunção cerebral em muitas configurações psicológicas e biomédicas.

Resumo

Foram administrados a ratos neonatais relativamente alta concentração de álcool etílico (11,9% v/v) durante dias pós-natal 4-9, quando o cérebro do feto passa por rápida mudança organizacional e é semelhante ao acelerado alterações cerebrais que ocorrem durante o terceiro trimestre em seres humanos. Este modelo de transtornos do espectro do álcool fetal (FASDs) produz danos cerebrais graves, imitando a quantidade e o padrão de esporádico que ocorre em algumas gestantes alcoólicas. Nós descrevemos o uso de rastreamento eyeblink condicionamento clássico (ECC), uma variante de ordem superior de aprendizagem associativa, para avaliar a disfunção hippocampal a longo prazo que é normalmente vista na prole adulta expostas ao álcool. Com 90 dias de idade, roedores foram cirurgicamente preparados com gravação e eletrodos estimulantes, que medida eletromiográfica (EMG) piscarem a atividade do músculo da pálpebra esquerda e entregues leve choque posterior para o olho esquerdo, respectivamente. Após um período de recuperação de 5 dias, eles foram submetidos a 6 sessões de rastreamento ECC para determinar as diferenças de aprendizagem associativa entre álcool-expostos e ratos controlam. Rastreamento de ECC é um dos muitos procedimentos ECC possíveis que podem ser facilmente modificados usando o mesmo equipamento e software, para que podem avaliar diferentes sistemas neurais. ECC procedimentos em geral, podem ser usados como ferramentas de diagnóstico para a detecção de patologia neural no cérebro de diferentes sistemas e diferentes condições que insultar o cérebro.

Introdução

It is quite hard to imagine that in today's day and age with better health care and access to health services, alcohol abuse remains a major global health concern. Unfortunately, it has been shown that an expectant mother who drinks a high amount of alcohol can have a child with severe brain damage and neurodevelopmental disorders that last a lifetime, as evident in those afflicted with fetal alcohol syndrome (FAS)1,2,3. In women with some confirmed history of maternal alcohol use, the developing fetus is also susceptible to small amounts of alcohol or different patterns of alcohol consumption that produce varying differences in blood alcohol concentrations. In this latter case, while the children may not exhibit the severe morphological or neurobehavioral disruptions as those with FAS, they may still exhibit lifelong cognitive disabilities and emotional disturbances that range from mild to severe3,4. Altogether, FAS and less severe forms of prenatal alcohol-mediated disruptions constitute a collection of fetal alcohol spectrum disorders (FASDs). It is no surprise that FASDs are completely preventable, but astonishingly estimates show that in populations where alcohol abuse is quite common, they remain the primary non-genetic cause of neural and cognitive disability, affecting about 2% to 5% of young US children and those in European countries such as France and Sweden. With respect to the incidence of FAS alone within the US, the prevalence is 2 to 7 per 1,000 live births5, implying that the overall incidence of FASDs to be much higher than that for FAS.

Neuroimaging studies conducted in children with FASDs have shown that they display brain abnormalities, such as a thinner corpus callosum6, smaller anterior cerebellar vermis7, and smaller hippocampus8. These brain abnormalities underlie some of the long-term neurocognitive disruptions observed in children with FASDs. The exact links that tie variations in maternal alcohol-mediated brain changes and variations in the profile (i.e., type, extent) of particular neurocognitive impairments have yet to be clearly determined. But as a starting point, the hippocampus is an excellent candidate for determining its susceptibility to prenatal alcohol effects. Indeed, children with FASDs exhibit deficits in hippocampal-mediated behaviors such as place learning9,10 and delayed object recall11.

Rodent models of FASDs have proven to be invaluable in elucidating the mechanisms leading to neurocognitive disruptions seen in children with FASDs. A well-established binge-exposure model that we have adopted involves delivering alcohol to rats during postnatal days 4-912,13, a period when the brain undergoes rapid synapse and dendritic contact formation, comparable to human fetal week 24 and extending into the 3rd trimester14,15,16,17. This particular model induces significant loss of hippocampal neurons18,19 and neurons in many other brain regions such as the cerebellum12,13,14,15,16,17,18,19,20,21,22,23, accompanied by severe impairments in cognitive functions spanning different domains21,24,25. Cognitive disruption from early alcohol exposure in rats may be assessed in different ways, particularly with eyeblink classical conditioning (ECC). ECC is a paradigm that has been utilized for more than a century to scientifically investigate the fundamental basis of learning26,27 and as such, provides a useful method to better understanding the adverse neurocognitive consequences resulting from fetal alcohol exposure. It is a very flexible paradigm that allows investigators to use a variety of different ECC procedures, any of which can be examined across many mammalian species ascending the phylogenetic scale (from mice to humans) and over different courses of brain development28,29,30,31. Furthermore, the fundamental neural circuits that mediate associative learning in this paradigm are supported by experimental and neuropsychological reports in these same species26,32,33,34,35,36,37.

One form of ECC, trace ECC is demonstrated in this paper (Figure 1). To provide context, it is compared against the more traditional form - delay ECC. The ECC paradigm was modeled after classical conditioning using dogs, first carried out by the Nobel-Prize winning physiologist, Ivan Pavlov. Pavlov discovered that certain stimuli such as tones do not naturally elicit salivation, but when it precedes and overlaps with the delivery of food, the salivary response can be strengthened from repeated presentations of the two, provided that this tone-food contingency is maintained. This is an example of delay ECC, with the notion that associative strength is mediated by immediate temporal contiguity between the two stimuli, thus making learning conditions optimal for an animal. He also tested other variations of the tone-food contingency, such as turning the tone off and leaving a "trace" period before delivering the food. When these two stimuli were discontiguous enough, it became much harder for the dogs to emit salivation responses prior to the delivery of the food. The discontiguity between the tone being turned off and the delivery of the food is thus an example of trace ECC. As rodents do not naturally salivate to the presence of food, more species-relevant stimuli such as mild shock are used instead; they also do not naturally emit defensive eyeblink responses to tones. With this backdrop, rodent ECC procedures involve presenting a tone at a given decibel level and pairing it in some fashion with mild shock to either the eyelid muscle (orbicularis oculi) or the temporalis muscle to elicit an eyeblink response. The tone is considered a conditioned stimulus (CS) while the shock is considered an unconditioned stimulus (US). In delay ECC, the CS is presented first; this stimulus remains on for a given duration. Afterwards, the US is delivered. These two stimuli overlap for a given duration, and then both terminate simultaneously; the resultant eyeblink response emitted due to the US is considered an unconditioned response (UR). In this procedure, rodents learn to emit eyeblink responses sometime after the CS is presented, but just before the US, in order to anticipate this aversive stimulus. The learned eyeblink response is referred to as a conditioned response (CR). For trace ECC, the CS and US are separated by a period of time that is void of stimuli known as a trace interval; they do not overlap in time as in delay ECC. During this interval, the animal is tasked to resolve the associational requirements between stimuli. Similar to delay ECC, learning occurs when the animal consistently emits a blink response after the CS turns off, but immediately before delivery of the US. Over some amount of acquisition training (CS paired with US), learning curves (i.e., based on different CR measurements) develop. Lesion and neuroimaging studies show that successful learning in delay ECC is dependent on having intact cerebellar-brain stem neuro-circuitry38,39,40, whereas trace ECC is a higher-order procedure that requires additional neural engagement from the hippocampus41,42,43,44 and other cortical structures45,46. Because of the timing-related requirements needed in order to acquire trace CRs successfully, this task is also more difficult to learn (even for normal subjects).

figure-introduction-9389
Figure 1: Trace eyeblink classical conditioning. An actual waveform is shown that is representative of an adult rat in the unintubated-control (UC) group. The tone CS (85 dB, 2.8 kHz) is first presented for 380 ms. A trace interval of 500 ms ensues, where no stimuli are present. Afterwards a shock US (1.6 mA) is delivered for 100 ms. Successful learning in this task occurs when the frequency (%) or amplitude (in volts) of eyeblinks during the conditioned response (CR) time window (Total CR period) increases over many sessions of training. In particular, rodents with an intact hippocampus will usually emit more well-timed CRs (Adaptive CRs) just prior to the onset of the shock US (within a 200-ms window). Startle responses (SRs) during the first 80 ms after tone CS onset and unconditioned responses (URs) are also measured. Non-associative SRs are typically low or nonexistent in well-trained rodents, while URs are expected to be high in frequency and amplitude. This task requires that the rodent learn to bridge the association between the CS offset and US onset (during the trace interval), therefore making it inherently more difficult to acquire compared to delay ECC. Please click here to view a larger version of this figure.

Here we demonstrate the adverse functional consequences of neonatal alcohol exposure that is delivered in a binge-like manner, as assessed by a trace ECC procedure that delivers an 85 dB tone CS (2.8 kHz) which remains on for 380 ms, followed by a 1.6 mA shock US which remains on for 100 ms, and these stimuli are separated by a trace period of 500 ms. We have reported on the utility of this behavioral assay in previous studies examining choline intervention and iron supplementation in mitigating the effects of neonatal alcohol exposure18,47. Indeed, trace ECC can be used as a diagnostic tool to assess neonatal alcohol-induced hippocampal pathology. The advantage it has over delay ECC is that it is more sensitive to detecting disturbances in hippocampal function, which is compromised in humans with FASDs.

Demonstration of ECC extends far outside the fetal alcohol field. Many variants of ECC (e.g., delay, trace, compound, reversal) can be used to elucidate ontogenetic differences in learning across development, the neurobiological basis of associative learning in normal mammals, as well as the vulnerabilities of different brain systems to many challenges, including (but not limited to) teratogens, environmental toxins, traumatic brain injury, neurodegenerative diseases, and psychiatric conditions.

Protocolo

NOTE: All procedures were approved and carried out in accordance with the policies set forth by the East Carolina University IACUC. Long-Evans rats were generated from females mated with male breeders. Pups from all three treatment groups (see 1.1) were generated within a litter from the same dam. Five litters were produced and each litter was culled to 8 pups on postnatal day (PD) 3. The remaining two pups from each litter were assigned to separate experiments. Both male and female offspring (one per exposure group) were included in the study. A total of N = 27 adult offspring were examined in this study; 3 rats were excluded due to broken 3T wire leads (see 3.1.1) which were irreparable on Day 1 of ECC training.

1. Preparation of Groups, Materials, and Solutions

  1. On PD 3, remove pups from the dam and place them on a thermo-regulated water heating pad to keep warm. Use a random selection procedure to place rat pups into one of three groups: (1) alcohol-intubated (AI); (2) sham-intubated control (SI); or (3) unintubated-control (UC). Carry out approved procedures for identification, such as [non-toxic] ink tattooing of their paws with a 30G x 1/2 in needle following a numbering scheme. Return the pups to the dam when finished with tattooing.
  2. Prepare an intragastric intubation tube(s) using polyethylene (PE) size 50 and 10. The overall length of this tube is user-dependent and can be adjusted accordingly.
    1. Use micro dissecting scissors to cut a 3 in piece of PE-50 tubing and a 6 in piece of PE-10 tubing.
    2. Carefully attach the PE-50 tubing to a sterile 22 G x 1 in hypodermic needle.
    3. Insert one end of the PE-10 tubing into the open end of the PE-50 tubing. A diagonal cut may be needed at the tip of the PE-10 tubing in order to direct it into the PE-50 tubing.
    4. Cut a small piece of PE-50 tubing (about 2-3 mm) and insert it on the open end of the PE-10 tube. This will serve as a visual stopper.
    5. Store the complete intragastric intubation tube in fresh 70% isopropyl alcohol to keep it sterile.
  3. Carry out aseptic procedures to prepare a stock milk solution in 50 mL bottles. The stock milk solution is based on a diet formula first established by West et al. (1984)48. Store the bottles at -18 °C until time of use. Thaw two bottles of milk using warm water prior to use.
    1. Draw out 7.16 mL of 95% ethyl alcohol (USP) using a sterile syringe and add it to one 50 mL milk bottle. This makes an 11.9% v/v alcohol solution that is delivered to rat pups over the first two feedings of the day (see 2.1.1); the total daily dose of alcohol is 5.25 g/kg/day. It is designed to deliver the alcohol in a volume (0.0278 mL/g per feeding) in enriched milk solution.
      NOTE: This amount can be adjusted based on litter size and expected usage over 3-4 days. The amount of alcohol added must also be adjusted in order to make an 11.9% v/v solution.
    2. Shake this bottle well and label it accordingly (i.e., 11.9% v/v Ethyl Alcohol in Milk).
    3. Label the second bottle of milk (without alcohol added) accordingly (e.g., Milk-Only) and use it for supplemental feedings as indicated in 2.1.1.
    4. Store both milk bottles in the refrigerator.

2. Neonatal Alcohol Exposure (Postnatal Days 4-9)

  1. Give AI and SI pups 4 total intubations per day starting on PD 4. Separate each intubation by 2 h. Because AI pups are intubated with an actual solution, each of their intubations are considered feedings.
    1. Intubate the AI pups with the 11.9% v/v Ethyl Alcohol in Milk solution during the first two feedings of the day, and then intubate them with the Milk-Only solution during the last two feedings of the day to supplement their growth.
    2. Intubate the SI pups 4 times without any solution every two hours, ensuring the same duration of PE-10 tube exposure that AI pups endure. The UC group does not receive any intubations.
  2. Remove pups from the dam and place them on a thermo-regulated water heating pad to keep warm. Weigh each pup and record its body weight (in g). Refer to a pre-made feeding chart to determine the intubation volume for each AI pup and note it in a record sheet.
    1. Place the 11.9% v/v Ethyl Alcohol in Milk solution in a warm water bath and shake it well.
    2. Intragastric intubation procedure:
      1. Flush out the intragastric intubation tube that was stored in 70% isopropyl alcohol well with warm water.
      2. Extract the correct amount of solution using a sterile 1 mL syringe.
      3. Dip the tip of the intubation tube (PE-10 end) in fresh corn oil (this facilitates insertion).
      4. Measure the length of the PE-10 tube from the pup's mouth to its stomach. Adjust the PE-50 stopper to guide with the stopping point.
      5. Carefully insert the PE-10 tube into the pup's mouth, proceeding down its esophagus, slightly passing through the gastroesophageal sphincter, and into its stomach. Examine the pup, stabilize it, and depress the syringe plunger to deliver the solution. Do this at a slow rate.
        NOTE: To avoid accidentally inserting the tube into the trachea, first direct the tube so that it curves and makes contact with the soft palate prior to proceeding forward. Use the palate as a guide, as the tube will naturally deflect off this region and be guided down the esophagus. Otherwise, any substantial deviation of the tip ventrally may cause it to enter into the trachea. It is best to remove the tube and not to proceed with the intubation if one is not certain about its entry position - reinsert the tube correctly on the next attempt.
      6. Carefully remove the PE-10 tubing and examine the pup for backwash of solution, blood, or physical injury. Replace pup with its littermates if it is fine. The entire intubation procedure takes approximately less than 1 min for each pup and approximately 4 min total for the 4 intubation-treated pups in each litter (2 AI, 2 SI).
      7. Intragastric intubation procedure for SI pups: Follow the same PE-10 insertion procedure as that for AI pups, but without any solution for the same duration (1 min).
      8. Return all pups back to the dam immediately after completing procedures for the last pup in the litter. Return the dam to the vivarium until the next feeding session (in 2 h).
      9. Flush out the intragastric intubation tube with warm sterile water and replace it in 70% isopropyl alcohol for storage. Flush the tube well with water prior to each feeding session.
      10. Repeat 2.2 (except weighing pups) to 2.2.2.9 for the second feeding session. At the last two feedings, intubate the AI pups with the Milk-Only solution using the same intubation volumes determined in 2.2.
  3. Weigh the rats at regular intervals such as on PD 15 (when eyes open), PD 21 (weaning), PD 30, PD 60, and PD 90 (surgery) to obtain representative growth curves.

3. Fabrication and Modification of Electrodes

  1. Fabricate one electromyographic (EMG) "headstage" for each rat (Figure 2). The headstage allows for recording of eyeblink responses via the eyeblink system (Figure 4).
    1. Construct a headstage that consists of two size 3T polytetrafluoroethylene (PTFE)-coated stainless steel wires (5 cm each), one size 10T PTFE-coated stainless steel wire (5 cm), three male contact pins, and one micro strip socket insulator that is cut-down to 3 holes (see 3.1.4).
    2. Strip off the PTFE coating from the 10T wire by grasping the center with a serrated high precision tweezer and removing the coating in both directions with the smooth high precision tweezer. Ensure that all traces of coating have been removed from this wire.
      1. Crimp one end of the 10T wire to a contact pin with a serrated platform dental plier; this will serve as a ground wire. Hold a 3T wire carefully with the smooth high precision tweezer 1 to 1.5 mm from one end. Strip off the 1 to 1.5 mm PTFE coating while leaving the rest of the coating intact. Crimp a contact pin to the exposed end of the 3T wire.
      2. Carry out the same procedures for the second 3T wire. Both wires will serve as the positive and negative leads of the EMG recording electrodes.
    3. Perform tug tests on all wires to ensure that they are secured to the pins. Take caution not to bend or damage the wires.
    4. Cut a segment of a socket insulator strip down to 3.5 holes (cut the middle of the fourth hole) with the cutting blade of a wire stripper. Scale down this segment to just 3 full holes and sand-down both sides if necessary. This helps to ensure that 3 full holes are available. Insert pin-wire units into the three holes of the micro strip until the crimped ends are flushed with the bottom edge of the insulator segment. The 10T assembly needs to be in one outer hole of the micro strip and not in the middle.
  2. Modify bipolar stimulating electrodes (Figure 2).
    1. Give each rat one bipolar stimulating electrode. This electrode applies a small amount of electrical current via a stimulus isolator (see eyeblink system) as the shock US during ECC. The electrodes are acquired from a manufacturer in twisted form and are shielded.
    2. Untwist the two metal leads 2-3 times to make a V-shape (spread 5 mm) and then use the smooth high precision tweezer to straighten each "prong" as much as possible. Scrape off 1 mm of shielding from each prong's tip (all around) with a razor blade. Inspect each prong for irregularities and bends, and correct if necessary without scraping off additional shielding.
  3. Remove manufacturing oil and foreign debris from the EMG headstages and bipolar electrodes by washing them in 95% ethyl alcohol. Allow them to dry then autoclave.

figure-protocol-10416
Figure 2: Electromyographic (EMG) recording electrodes and bipolar electrode. The finished EMG headstage (right, orange) is constructed from three male contact pins, two size 3T PTFE-coated wires, one size 10T PTFE-coated wire, and a modified micro strip. The three wires are approximately 5 cm each and are crimped to the contact pins. The finished bipolar electrode (right, white) is untwisted, re-straightened, and molded in a V-shape (5 mm split). Shielding is removed from the tips of the two prongs. Please click here to view a larger version of this figure.

4. Eyelid Surgery Procedure (Postnatal Day 90)

  1. Preparation of materials (see Materials for detailed supply information), animals, surgical, and non-surgical areas:
    1. Autoclave surgical instruments and supplies - the number in parentheses ( ) indicates approximately how much is needed per adult rat or measurement: surgical instruments (1 set per 4 rats, as approved by the ECU IACUC), gauze pads (3-4), cotton-tipped swabs (5-6), 20 x 20 wrap (4 per/surgery session), porcelain crucible (1), stainless steel microspatula (1), 0.9% saline (1 wash bottle), Petri dish (1), and 0-80 stainless steel screws (3/rat).
    2. Other sterile supplies needed: surgical blade size 10 (1 per 4 rats), surgical drape (1 per rat), veterinary ophthalmic ointment, povidone-iodine (1 wash bottle), 26G x 3/8" hypodermic needle (2), nickel-plated pin vise with #55 drill bit, nickel-plated flathead jeweler's screwdriver (1.8-2 mm blade).
    3. Prepare a sterile holding area for all surgical tools and supplies using an approved research/medical grade disinfectant. Place materials on this space when the area is ready.
    4. Prepare a sterile surgical space using an approved research/medical grade disinfectant. This space contains a thermo-regulated water heating pad, stereotaxic apparatus fitted with a rat anesthesia mask, glass bead sterilizer, and isoflurane gas vaporizer (for anesthesia). The vaporizer has tubes to the anesthesia mask and to an induction chamber located on a separate space for non-sterile animal preparation procedures; each tube is controlled by its own valve.
    5. Scrub hands and arms thoroughly with antimicrobial soap. Without touching the inside, pre-open any items that have been packaged in sterilization pouches or wraps. Don sterile gloves using aseptic procedure and transfer all pertinent items to the surgical area. Set the drill bit at the proper depth in the pin vise (~ 2 mm) and prepare the screwdriver. Cover the sterile materials with a sterile wrap until the surgery is ready to begin.
    6. Prepare a non-sterile space with a weighing scale, electric fur trimmer, sterile 1 mL syringes with 26G x 3/8 in needles (1 per rat), surgery log, and buprenorphine (0.03 mg/mL concentration) administered 0.1 mL/100 grams.
      CAUTION: Buprenorphine is a DEA schedule III semisynthetic opioid, and must be locked and logged appropriately.
    7. Check the isoflurane vaporizer for appropriate gas level; add more gas if it is low. Leave the gas flow and mixture knobs off for now. Turn on the O2 tank and check that there will be enough gas for all surgeries.
    8. Weigh each rat and record its body weight in the surgery log. Use a buprenorphine injection chart to determine the proper injection volume.
    9. Turn on the vaporizer valve to the induction chamber and leave the valve to the surgery mask off. Turn the mixture to 3 and flow rate to 3 (3% isoflurane with 100% O2 as the carrier gas at a volume of 3 L/min).
    10. Place a rat in the induction chamber and allow it to reach proper anesthetic plane (slow breathing, lack of pedal reflex, lack of blink reflex). Remove the rat from the chamber once it has reached anesthetic plane.
    11. Shave its head using the fur trimmer, exposing a sufficient amount of skin for the incision site and the left eyelid. If necessary, place it back in the induction chamber to reach anesthetic plane again before resuming with the trimming.
    12. Disinfect the exposed skin by applying alternating rubs of isopropyl alcohol and povidone-iodine three times. If necessary, place it back in the induction chamber to reach anesthetic plane again, prior to transferring to the surgery table.
  2. Surgery
    1. Turn on the vaporizer valve to the anesthesia mask and shut off the valve to the induction chamber. Adjust the mixture to 2.5 and flow rate to 2 (2.5% isoflurane with 100% O2 as the carrier gas at a volume of 2 L/min). Transfer the rat to the stereotaxic apparatus and follow standard procedures in securing its head to the incisor bar and ear bars (see Geiger et al., 200849 for an example).
    2. Give the rat a pre-surgical injection of buprenorphine (SC) and carefully dispose of the needle (uncapped) in a sharps container. Place a sterile surgical drape on the rat, exposing just the surgical area and isolating it from the rest of the body.
    3. Don a surgical mask, surgical cap, surgical gown, goggles, and any other personal protective equipment required by the IACUC. Wash and scrub hands and arms thoroughly with antimicrobial soap. Don sterile gloves using sterile procedure.
    4. Apply a small amount of ophthalmic ointment to both eyes using a cotton-tipped swab to prevent them from drying.
    5. Proceed with the surgery when the rat exhibits proper anesthetic plane. Monitor the rat continuously throughout the surgery and check the isoflurane level periodically. Adjust the flow and mixture knobs accordingly during surgery based on the rat's response to the anesthesia.
    6. Make an anterior-posterior incision at the midline of the cranium with a scalpel blade. This incision should expose enough area in front of the eyes (i.e., exposing the frontal bone) and slightly behind the lambdoid suture.
    7. Scrape away the periosteum on top of the cranium carefully not to cause excessive bleeding. Wipe off excess connective tissue and blood with a cotton-tipped swab.
    8. Drill a hole using the drill bit with the aid of a pin vise, starting directly behind the coronal suture on one parietal bone. Remove any blood and bone debris with a cotton-tipped swab. Grasp a 0-80 screw by the threading with splinter forceps and fasten it to the hole with the jeweler's screwdriver; tighten-down the screw just enough without damaging cortical brain tissue (usually 3-4 full turns).
    9. Follow the same procedures described in 4.2.8 to fasten two more 0-80 screws to the skull, one directly behind the coronal suture of the opposite parietal bone and one directly anterior to the right lambdoid suture. It has been found that 3 screws are sufficient for anchoring the dental cement (see 4.2.18) to the cranium, as a fourth screw (anterior to the left lambdoid suture) would impede the placement of the bipolar electrode.
    10. Remove an EMG headstage from the Petri dish. Face the headstage so that the 10T wire is on the rat's right side. Bend the 10T wire upward, making it parallel with the bottom edge of the micro strip. Give it a slight bend to the right side so that the wire can come around the anterior and posterior 0-80 screws. Set it aside but close enough to reach.
    11. [Assuming one is right-handed] Place 3 in dressing forceps in the left hand and 4 in dressing forceps in the right hand. Grasp the upper skin at the incision site of its left eye with the 4 in dressing forceps and direct the 3 in dressing forceps towards the corner of this eye; grasp the skin at this corner. Maintain the grasp with the 3 in dressing forceps while releasing the 4 in dressing forceps.
    12. Take one 26G x 3/8 in needle and insert it through the corner of the eyelid; rotate the needle so that the beveled side is face-up. Use the micro dissecting forceps with platform to insert the middle 3T wire into the needle's hole. Push it through the hole a few centimeters without going down completely; this wire is the negative lead.
    13. Carry out the procedures described in 4.2.11 and 4.2.12 to insert the outside 3T wire into the middle portion of the eyelid; this wire is the positive lead.
    14. Grasp both needles with one hand while grasping the headstage with the other hand (or forceps). Pull the needles away from the eyelid while guiding the headstage in the same direction in one continuous movement. If necessary, rotate the headstage so that the 10T wire is towards the animal's right eye; do not allow the 3T wires to cross. Use fine tipped forceps to double-check that the positive lead is in the middle of the eyelid.
    15. Adjust the headstage so that it is centered between the eyes and is in an optimal position atop the frontal bone, anterior to the bilaterally-inserted screws. Hold the headstage with one hand and hold the 3 in dressing forceps with the other hand. Wrap the 10T wire around one or both screws on the 10T side.
    16. Place 3 in dressing forceps in one hand and 4 in dressing forceps in the other hand. Use the 3 in dressing forceps to grasp the skin at the incision site towards the left temple. Use the 4 in dressing forceps to create a small "pocket" by separating the skin (i.e., superficial fascia) from the temporalis muscle. Use the iris scissors to cut away more connective tissue, working in towards the corner of the left eye, to increase the size of this pocket. Be careful not to go in too deep or cut any blood vessels.
    17. Take a bipolar electrode and shape the wire leads so that they can be fitted along the curvature of the temporalis muscle, while the two prongs are situated (dorsal and ventral) posterior to the left eye (see video), and the bottom end of the bipolar electrode can be situated straight atop the cranium. Allow enough distance between the headstage and this electrode for the commutator cable plugs (Figure 3) to attach without impediment.
    18. Pour dental cement powder into the crucible - start with about 1/3 of the crucible, and then scale the amount as necessary. Add the liquid component until the consistency is watery, and mix these components with the spatula. When the cement's consistency becomes more viscous, apply it to the incision site - covering all edges of the skin with at least 1/8 in borders.
      1. Apply enough cement to fortify the headstage and bipolar electrode without preventing the rat from closing both of its eyes. Quickly wipe off any cement that drips onto unwanted areas of the rat's fur.
    19. Ensure that at least 4-5 threads of the bipolar electrode are left unsealed by cement so that the bipolar plug can be twisted on (Figure 3). Remove excess cement from the headstage - the top of the micro strip and the three contact pins must be clean. The cement hardens quickly and may easily prevent full coupling of any of these electrodes to the commutator cable plugs. Use splinter forceps to remove excess cement that has partly dried.
    20. Wait for the cement to harden; it becomes clear. Use the micro dissecting scissors to snip off excess length from the two 3T wires, leaving a few centimeters of working room.
    21. Grab the micro dissecting forceps with platform on the left hand while grabbing the micro dissecting forceps with fine points on the right hand. Grasp one 3T wire with the left forceps slightly in front of the eyelid. With the right forceps, push the eyelid up to expose more 3T wire and hold it there. Release the left forceps and use the left hand to grasp the headstage (ensure it is secure by now). Use the right forceps to strip off some PTFE shielding, which allows the wire to make contact with the orbicularis oculi muscle.
      NOTE: Take caution not to pull too hard on a 3T wire, as it may detach from the contact pin. If a wire detaches, then it will not be possible to replace the contact pin as the hardened cement will not release freely from the cranium without causing bone breakage.
    22. Perform the steps in 4.2.21 to strip off excess PTFE from the second 3T wire.
    23. Grab the two micro dissecting forceps as stated in 4.2.21 (with platform on left, fine points on right). Position the left forceps slightly in front of one 3T wire while leaving room for the right forceps to be positioned directly in front of the eyelid. Grasp the wire with both forceps.
      1. Create a "hook" by keeping the right forceps still and rotating the left forceps up and around towards the eyelid; do this in one motion. Carefully release the right forceps, and then the left forceps.
        NOTE: Hooking the electrodes on the eyelids help to minimize the possibility of them rubbing onto the cornea. This also minimizes the possibility for wire breakage during any point in the behavioral testing phase. While hooking does not fully prevent the wire from rubbing against the cornea for all animals, they typically show no signs of eye damage as reflected by their high blink amplitudes (measured by the digital oscilloscope in 5.1.7) and from daily post-surgical health observations (excessive tearing, partial eyelid closure, lack of mobility from eye damage). If a rat shows initial signs of discomfort, it is anesthetized with isoflurane (see 4.1.10) and its electrodes are re-examined and/or re-positioned. Ophthalmic ointment is applied to prevent the cornea from drying. The rat is observed daily for any post-procedural eye complications and should they persist, then seek veterinary care. Rats that exhibit severe eye complications which cannot be corrected with electrode re-positioning or with veterinary treatment, are humanely euthanized according to the standard operating procedures of the ECU IACUC.
    24. Perform the steps in 4.2.23 for the second 3T wire. Snip off excess wire using the micro dissecting scissors.
    25. Use one hand to release the rat from the ear bars while supporting its body with the other hand. Inspect its head for any blood or debris, clean up if necessary, and give it a post-operative injection of buprenorphine.
    26. Place the rat in a recovery bin that has a source of heat (such as a thermo-regulated water heating pad) to aid recovery. Mark in the surgery end time in the surgery log and any pertinent notes about the rat during surgery. Monitor the rat for proper respiration and when it exhibits sternal recumbency or moves about, it may be returned to its home cage.
    27. Re-sterilize the instruments (except micro dissecting forceps - as they may be damaged) using the bead sterilizer and ensure that the surgical area remains aseptic, and repeat aseptic procedures if multiple eyelid surgeries will be performed.

5. Trace Eyeblink Classical Conditioning Procedure

figure-protocol-25808
Figure 3: Modified operant conditioning box for eyeblink conditioning. Rats are freely-moving mammals, and therefore a rotating commutator is used for maintaining electrical signal contact from the EMG and bipolar plugs that are attached to the head. The commutator is attached to the arm of the stanchion, which is counter-weighted for alleviating pressure on the rat. A piezo tweeter (speaker) delivers a 2.8 kHz tone at 85 dB and these values are calibrated regularly. Acoustical foam assists with attenuating environmental noise. Please click here to view a larger version of this figure.

figure-protocol-26692
Figure 4: Eyeblink conditioning system. This custom-built system consists of an EMG Integrator unit that filters and amplifies incoming signals from the rats, a Stimulus Control unit that delivers various stimuli in addition to tones and shocks, a pre-amplifier for each operant box to increase EMG signal gain, and a stimulus isolator for each operant box; it provides varying shock levels (in mA). A digital oscilloscope (not part of the stock eyeblink system) is used for diagnostic purposes during habituation and acquisition. Please click here to view a larger version of this figure.

  1. Begin habituation and acquisition training 5 days after surgery. Give each rat one day of handling and habituation to the training apparatus - consisting of a modified operant conditioning box that is housed in a larger sound-attenuated chamber (Figure 3) - and follow with 6 days of acquisition training. Carry out the habituation and acquisition sessions using a custom-built eyeblink system (Figure 4).
    1. Create a training log file and print it out to use for daily record keeping. This log should have the squad of rats pre-assigned pseudo-randomly (or other randomization method) to their training boxes.
    2. Power on the eyeblink system, computer, and run the eyeblink software. This version of the software has different modules (or applications) that run independently. Run the Animal module to create a *.RAT file that contains subject information (session number, animal ID, sex, weight, and box number). A single RAT file manages up to four rats, which comprises a squad of subjects. Enter the values accordingly and save the file. Create a separate RAT file for each squad of rats to be trained.
    3. Transfer the rats from their vivarium to the testing room and close the door. Handle each rat for 5 min.
    4. Transfer a rat to its designated box and connect the EMG and bipolar plugs from the commutator cable to the corresponding EMG headstage and bipolar electrode on its head.
      NOTE: On first exposure to the commutator cable, a rat may struggle and show signs of stress. Handle the rat carefully and allow breaks in between unsuccessful attachments to alleviate its stress.
    5. Use a commutator that rotates 360° while maintaining electrical signal delivery/reception as a rat moves freely within a box. It has 5 channels (3 for the EMG electrodes, 2 for the bipolar electrodes) leading into the EMG Integrator unit, which filters and amplifies the raw signal.
    6. Determine that the rat is moving freely, and that it is not hindered by the weight of the commutator cable assembly or stanchion arm. Adjust the counter weight at the back of the stanchion if necessary. Check that all plugs are secure then close the box door. Perform the same connection/check procedure for all rats.
    7. Use an oscilloscope to observe their EMG activity for abnormal signals (e.g., high frequency and/or high amplitude electrical activity) and a video surveillance system to check their status (e.g., motor activity, sensitivity to environment, signs of pain) if available. Note any problems that are observed in the training log.
    8. Allow rats to habituate to their chambers for 10 min, and then return them to their homecages.
    9. Clean and disinfect the operant boxes, sweep the floor, and clean the table(s). Carry out these procedures after every session.
  2. Acquisition training occurs over 6 consecutive days (sessions).
    1. Day 1: Transfer a rat to its designated box and connect the EMG and bipolar plugs from the commutator cable to the corresponding EMG headstage and bipolar electrode on its head. Carry out the same procedures indicated in 5.1.6 and 5.1.7.
    2. Turn on the stimulus isolators and set the current to be delivered at 0.4 mA (4% of 10 mA as shown in video). The isolators deliver electrical current in alternating fashion (i.e., from trial to trial), between the dorsal and ventral prongs of the bipolar electrode. This helps reduce muscle fiber fatigue (at each muscle site) over repeated stimulus deliveries.
    3. Observe all eyeblink responses emitted and tolerances exhibited on each trial for all rats. After every second trial, increase the shock US intensity by 0.4 mA for each rat, until 1.6 mA is reached (on Trials 7 and 8). Double-check that all rats are responding normally in their boxes, that all amplification and gain settings are constant, and for proper electrical signals (i.e., low/little EMG noise) coming from them. Use a shock US intensity of 1.6 mA for all days of acquisition training.
      NOTE: If a rat exhibits pain to a given shock level (e.g., jumping high off the floor, climbing on walls, running around), the trial is paused and it will be returned to the previous mA setting (0.4 mA below) for two trials. Afterwards, the rat will receive the higher shock value that it did not tolerate again and if tolerance is shown, it will receive increasing values until 1.6 mA is reached. If it cannot tolerate any value, then the next lower value (in 0.4 increments) at which it tolerates will be used throughout training.
    4. Use an oscilloscope to observe their EMG activity for abnormal signals (e.g., high frequency and/or high amplitude electrical activity) and a video surveillance system to check their status (e.g., motor activity, sensitivity to environment, signs of pain).
      NOTE: Explanation of Trace ECC: A representative trial epoch with captured EMG waveforms is illustrated in Figure 1 and the trace ECC procedure is explained in detail in the video. The trace conditioning training file is set to deliver 100 trials (90 paired CS-US trials and 10 CS-only trials on every 10th trial) with an average inter-trial interval of 30 sec. The entire training session lasts approximately 52 min (assuming no stoppages). All rats are naïve in Session 1 and will develop differential learning curves (as determined by the expression of CRs) as they progress through several days of training.
    5. Start the training: Run the Blink software module. When prompted, select the correct RAT file and the training file for "trace" eyeblink conditioning.
    6. Write down the start time and the experimenter's name in the training log. Monitor all activity at this point: proper EMG signals, good blink responses to the shock US (i.e., high/frequent URs), health status of the animals, and proper hardware function. Write any noteworthy remarks in the training log.
    7. Data collection is captured automatically by the software as RAW files (one per rat, per day). The RAW files contain EMG amplitude (in volts), frequency counts, latency, and areal data for startle responses (SRs), URs, and CRs (total and adaptive). Shock artifact obscures the first 100 ms of the UR period, therefore only the last 140 ms of the UR period contain UR data.
    8. At the end of training, the software will automatically close. Remove all rats from their training boxes and return them to the vivarium.
    9. Repeat steps 5.2.5 - 5.2.6 for all subsequent training days. Before starting the Blink module on a given day, update the session number within the RAT file. This allows for creation of new RAW files for all rats that day. Each rat should have 6 RAW files, assuming that none has been removed from the training.
  3. Process the RAW files and create a file that has been filtered for statistical analysis.
    1. Run the Analysis module. Review each session for each rat on a trial-by-trial basis for problematic trials. This is carried out to screen for trials that may be compromised due to various reasons (e.g., excessive pre-CS baseline activity, excessive movement, electrode detachment, cabling/wire issues). The software has algorithms that assist the experimenter with detecting and removing "bad trials" from being part of the filtered data set.
    2. Import the filtered data into a spreadsheet program and perform pertinent statistical analyses.

Resultados

O software eyeblink é capaz de fornecer um grande e abrangente conjunto de dados para vários tipos de medições. Por questões de brevidade, relatamos neste estudo, representante os resultados para a aprendizagem e desempenho medidas que incluem adaptável porcentagem de CR, adaptável amplitude de CR, percentagem de UR e amplitude de UR. O período adaptativo de CR foi escolhido como ele representa a aquisição de respostas eyeblink bem-cronometrada sobre treinamento repetido, como resultado de maior plasticidade sináptica no hipocampo durante rastreamento ECC50,,51,52. As medidas de UR foram escolhidas para elucidar se os défices de aprendizagem neonatal induzida pelo álcool em rastrear ECC foram devido a perturbações na aprendizagem associativa ou interrupções na resposta ao choque nos - o que pode indicar diferenças motivacionais ou motor, em vez de aprender as diferenças entre os grupos de tratamento. Os dados para cada medida foram analisados usando 2 (sexo), x 3 (grupo Neonatal), x 6 (sessão) misturado ANOVAs, com sessão como o fator de medidas repetidas. Significativos efeitos principais para tratamento neonatal foram analisados usando testes post hoc de Tukey e interações significativas foram analisadas usando testes de efeitos simples. Todas as análises estatísticas foram realizadas utilizando um nível mínimo de alfa de 0,05 e resultados em gráficos são média ± SEM.

Começando com a medida de porcentagem de CR adaptável, a ANOVA indicou um significativo efeito principal do grupo neonatal, F(2,21) = 11,69, p < 0.001, mas nenhum significativo efeito principal do sexo (p = 0,71) ou interação significativa entre esses fatores (p = 0.20). Como esperado, percentagem de CR adaptável aumentou durante as seis sessões de treinamento, F(5, 105) = 81.15, p < 0,001 e as diferenças entre os grupos neonatais eram dependentes de algum nível de sessão, F(10, 105) = 4,58, p < 0.001. Não havia nenhuma outras interações significativas que envolvem o fator de sessão. Da mesma forma para amplitude de CR adaptável, houve novamente um significativo efeito principal do grupo neonatal, F(2,21) = 22.32, p < 0.001, mas nenhum significativo efeito principal do sexo (p = 0,21) ou interação significativa entre esses fatores (p = 0,48). Amplitude de CR também aumentou significativamente ao longo das seis sessões de treinamento, F(5, 105) = 59.27, p < 0,001 e as diferenças entre os grupos neonatais eram dependentes de algum nível de sessão, F(10, 105) = 4.31, p < 0.001. Em geral, as duas medidas de CR mostraram diferenças significativas entre os meios do grupo e estes meios separados significativamente em diferentes sessões de treinamento. Para confirmar que os grupos diferiam significativamente, testes post hoc de Tukey mostraram que os ratos (AI) álcool-intubado realizada significativamente pior em ambas as medidas CR do que o unintubated-controle (UC) e ratos de (SI) de Souza-intubado (p < 0,01 para porcentagem de CR; p < 0.001 por amplitude CR), que não diferiram entre si (pdo > 0,05). Efeitos simples testes realizados no grupo Neonatal significativa x interações de sessão para as duas medidas de CR, confirmadas que os ratos AI foram mais significativamente afectados em adquirir CRs começando na sessão 2 e continuando a sessão 6 em comparação com ratos tanto UC e SI (todos os p< 0.05), que não diferiram entre si ao longo de seis sessões. A única exceção foi a amplitude de CR adaptável para ratos de SI não começou diferir significativamente dos ratos AI até sessão 3. Estes resultados são mostrados na Figura 5A, 5B.

Não havia diferenças significativas nas medidas UR devido ao sexo, grupo neonatal ou interações desses fatores com o fator de sessão. Estes resultados negativos indicaram que cada grupo era capaz de emitir respostas eyeblink ao choque-nos igualmente, que os défices de aprendizagem observados nos ratos AI não foram influenciados pelas diferenças motivacionais ou motor em piscar (figura 6A, 6B).

figure-results-4600
Figura 5 : Aquisição de rastreamento condicionado responder (média ± SEM). Exposição precoce de álcool (Grupo AI) afetado significativamente a aquisição de percentuais adaptável resposta condicionada (CR) (A) e amplitude (B). Rastreamento de ECC é inerentemente difícil de adquirir, portanto, as medidas são relativamente mais baixas para todos os grupos - com atraso ECC, percentagens podem chegar a 80-85% em modelos de roedores de FASD21,53. No entanto, o rastreamento de procedimento ECC é mais desgastante para o hipocampo, que é suscetível aos efeitos do álcool durante o desenvolvimento precoce do cérebro. * = p < 0.05, * * = p < 0,01, * * * = p < 0.001 entre ratos UC e AI; tamanhos de amostra são fornecidos em parênteses. Clique aqui para ver uma versão maior desta figura.

figure-results-5768
Figura 6 : Aquisição de respostas unconditioned (média ± SEM). Desempenho eyeblink (percentagem de UR e UR amplitude) não foi significativamente diferente entre os grupos. A falta de diferenças indicam que a intensidade do choque utilizada durante o treinamento de aquisição não alterou diferencialmente motivação nos ratos AI ou sua capacidade de produzir defensiva piscar respostas ao choque, em comparação com os dois grupos de controle (UC e SI). Tamanhos de amostra são fornecidos em parênteses. Clique aqui para ver uma versão maior desta figura.

Discussão

Filhotes de rato neonatal que receberam álcool etílico durante dias pós-natal 4-9 exibiram rastreamento eyeblink condicionado deficiências na idade adulta. Estes resultados suportam a ideia de que o álcool é um teratógeno com suportando os efeitos prejudiciais sobre a função do hipocampo. Globalmente, condicionado a responder no processo de rastreamento foi menor para os ratos expostos ao álcool em comparação com ratos em ambos os grupos de controle. As deficiências de aprendizagem associativa em ratos expostos a álcool não foram influenciadas pelas diferenças motivacionais ou motor (i. e., sem diferenças de piscar a intensidade do choque U.S.).

Enquanto traço ECC é uma ferramenta de diagnóstico útil para elucidar induzida pelo desafio hippocampal neuropatologia, os resultados deste método devem ser colocados no contexto adequado. Em primeiro lugar, os principais elementos processuais nesta demonstração envolveram a entrega específica de álcool durante uma conhecida janela de vulnerabilidade para o cérebro em desenvolvimento, fabricação de hardware de eléctrodo que permite a gravação da atividade eletromiográfica e entrega de choque, através da implantação cirúrgica do hardware acima e subsequentes ensaios em animais usando um paradigma de aprendizagem que avalia uma função cognitiva de interesse. Em cada fase do processo, deve-se tomar cuidado para não causar danos desnecessários/não-intencionais para os temas de roedores e monitorar seus sinais de saúde regularmente. Seus resultados comportamentais fornecem a "janela" para a cognição, uma construção psicológica que é somente com precisão descrito quando sua saúde não seja comprometida por erros experimentais englobando a dosagem de álcool, defeitos de hardware ou implantação cirúrgica. Assim, cada elemento processual no processo de investigação deve ser implementado de forma som para garantir que os resultados do ECC podem ser extrapolados para achados em seres humanos. Em segundo lugar, o paradigma ECC oferece uma visão sobre a natureza da aprendizagem associativa, mas deve ter cuidado para não estender conclusões usando esta abordagem e amplamente atribui-los para outros domínios cognitivos - como memória de trabalho, as memórias de curto/longo prazo e consciência - a menos que um incorporou algumas facetas destes domínios dentro de um estudo ECC pelo delineamento experimental. Por exemplo, esta demonstração analisou a fase de aquisição da aprendizagem do ECC de rastreamento, mas não examinar a retenção da memória nos ratos após eles completaram o treinamento. Memória é, portanto, um processo psicológico independente deve ser avaliadas, além de aprender. Por design, pode-se incorporar um intervalo de retenção de memória para avaliar qualquer capacidade de memória de curto prazo ou a longo prazo. Em terceiro lugar, o reconhecimento de que há memória paralelo sistemas54 que podem funcionar simultaneamente, juntamente com fatores motivacionais, experienciais e hormonais que contribuem para o comportamento, é essencial para compreensão associatividade (durante ECC) é mas um dos muitos processos que revelam o que é "bom" ou "pobres" sobre aprendizagem. Por último, rastreamento ECC não é uma tarefa puramente hipocampo-dependente, como outras regiões do cérebro podem mediar entre algum componente do CR. Assim, uma compreensão das interacções entre os diferentes circuitos neurais e/ou o tipo de estímulo de parâmetros que são utilizados em um estudo, deve ser tomado em consideração quando fazendo implicações com base nos resultados discretos. O cerebelo, por exemplo, também contribui para rastreamento ECC, onde influencia as características topográficas do CR e CR timing, particularmente quando o ISI é curto em duração. Rastreamento ECC não é afetado em humanos com danos Cerebelares, que são testados com um intervalo de tempo de rastreamento (1.000 ms), mas é afetado em quem recebe o rastreamento mais curto intervalo (400 ms)34. Além disso, lesões bilaterais do córtex pré-frontal medial dorsal (mPFC) que se destinam as regiões agranular medial e cingulado anterior em ratos, evitar aquisição de rastreamento CRs55, enquanto a destruição do mPFC caudal em coelhos produz semelhante resultados46. Esses achados também destacam a importância de considerar as diferenças de espécie no pré-frontal contribuições Cerebelares-cérebro-tronco conduzida aprendizagem associativa, como rastreamento de ECC. Enquanto exposição neonatal álcool durante a aquisição de 4-9 prejudicados PD de 500 ms rastreamento CRs para adulto ratos neste estudo e outros47,56, isto não é o mesmo caso para neonatais ratos expostas ao álcool que experimentam um intervalo de rastreamento de 300 ms, mesmo quando desafiado em uma dose relativamente alta de álcool (5 g/kg)57, sugerindo que a deficiência de rastreamento em ratos expostos a álcool é dependente da duração do intervalo de rastreamento.

Neste estudo, o hipocampo foi enfatizado como sendo extremamente importante para mediar rastreamento ECC e quando desafiados pela exposição de álcool neonatal, exposições dano neural, como refletido por deficiências na aquisição de rastreamento CRs. Isso deve advertiu, no entanto, que os circuitos de haste de cérebro-cerebelo, particularmente o núcleo interpositus, são essencial para muitas facetas do ECC, incluindo a aquisição, expressão e características topográficas do CR, dependendo do tipo de tarefa ECC, incluindo rastreamento ECC36,40,55,58,59. Com efeito, este circuito neural interage com o hipocampo para dirigir a expressão de Sir durante formulários de ordem superior do ECC, como rastreamento ECC60. Se a exposição de álcool durante o desenvolvimento precoce do cérebro afecta especificamente hippocampal função em rastreamento ECC não está inteiramente claro. Muitas regiões cerebrais diferentes são vulneráveis ao insulto de álcool precoce, incluindo o mPFC, cerebelo e hipocampo18,19,23,,47,61,62, e é muito provável que o álcool perturba o funcionamento dessas estruturas em diferentes graus e para variar, mas funcionalmente importantes diferenças em muitos procedimentos ECC. Apesar das armadilhas quanto à interpretação dos resultados de estudos de rastreamento ECC, aquisição bem sucedida de rastreamento CRs foi mostrada para contar pelo menos com um hipocampo intacto, como suportado por lesão animais estudos42,44,63,64,65. Este procedimento assim continua a ser uma abordagem altamente valiosa para demonstrar as ligações entre a exposição do desenvolvimento do álcool para rastreamento condicionado a responder porque os circuitos neurais subjacentes, é muito melhor entendido do que a de outras tarefas, hipocampo-dependente, como lugar de aprendizagem no labirinto de água Morris, reconhecimento de objetos novos e contextuais e rastreamento de medo condicionado.

ECC como um método comportamental a "ensaiar" cognição, tem aplicabilidade generalizada no campo do desenvolvimento neuroteratology. Com efeito, descobertas recentes de nosso laboratório de apoiar a noção de que o hipocampo em desenvolvimento é altamente sensível aos efeitos do álcool, que podem ser atenuados por diferentes estratégias intervencionista18,47. A principal vantagem aqui é que com uma melhor compreensão dos défices de aprendizagem ECC de rastreamento induzida pelo álcool, elas podem ser preditivas de outros problemas em funções hippocampal baseado fora de aprendizagem associativa - particularmente aqueles conhecidos ser mediado pelo mesmo neurocircuitos hippocampal.

Aplicativo de rastreamento ECC e suas variantes (por exemplo, atraso, reversão, discriminação, composta) para elucidar os mecanismos neurobiológicos e sistemas neurais envolvidos na aprendizagem associativa, pode ser estendido além do campo de pesquisa do álcool fetal. Por exemplo, este paradigma tem recebido muita atenção em casos humanos e modelos animais de condições psiquiátricas como esquizofrenia66,67, doenças neurodegenerativas, como a doença de Alzheimer68,69e drogas de abuso70,,71,72. Seus benefícios como um método de pesquisa para avaliar disfunção e função neurocognitive são, portanto, evidentes em muitas disciplinas psicológicas e biomédicas, incluindo neurociência.

Divulgações

Os autores não têm nada para divulgar.

Agradecimentos

Este trabalho foi financiado por um subsídio para TDT de álcool bebida médica Research Foundation (ABMRF).

Materiais

NameCompanyCatalog NumberComments
Neonatal Alcohol Exposure
190 Proof Ethyl Alcohol (USP)Pharmco-AAPER225-36000 [ECU Medical Storeroom]Can be substituted; should be USP; avoid using 200 proof ethyl alcohol
Container/Basket for PupsAny
Corn OilAnyFood grade
Heated Water Therapy Pump w/ PadsGaymarTP-500To keep pups warm; can be substituted
Hypodermic Needles 22G x 1 in, SterileAny
Hypodermic Needles 30G x 1/2 in, SterileAny
Isopropyl Alcohol 70%EMD MilliporePX1840-4 [Fisher Scientific]Can be substituted; reagent grade
www.fishersci.com
Long-Evans Rats (Female and Male Breeders)Charles River LaboratoriesN/A [ECU Dept. of Comparative Medicine]Age and weight need to be specified; pricing varies by these factors
www.criver.com
Micro Dissecting Scissors, 3.5 in, 23 mm BladesBiomedical Research Instruments11-2200For cutting PE tubing
brisurgical.com
Polyethylene 10 Tubing (0.011 in. I.D.; 0.024 in. O.D.)BD Diagnostic Systems22-204008 [Fisher Scientific]Can be substituted
www.fishersci.com
Polyethylene 50 Tubing (0.023 in. I.D.; 0.038 in. O.D.)BD Diagnostic Systems22270835 [Fisher Scientific]Can be substituted
www.fishersci.com
Regulated water heater or baby milk bottle warmerAnyOptional; helps with warming up cold milk solutions
Tuberculin Syringes, Sterile, 1.0 mlAny
Tuberculin Syringes, Sterile, 10 mlAnyCan be used to draw out ethyl alcohol or use appropriate size micropipet
Weigh ScaleAnyShould have good resolution (in gram units)
NameCompanyCatalog NumberComments
EMG Headstage Fabrication and Bipolar Electrode Modification
Bipolar Electrode, 2 Channel SS TwistedPlastics One, Inc.MS303/2-B/SPC  ELECT SS  2C TW .008"Must specify custom length of 20 mm below pedestal
www.plastics1.com
Centi-Loc Strip Socket Insulator (aka, Micro Strip)ITT Cannon / ITT Interconnect SolutionsCTA4-IS-60* or CTA4-1S-60**Depends on vendor; see www.onlinecomponents.com or www.avnetexpress.avnet.com
Dental Pliers, SerratedCMF Medicon390.20.05Can be substituted; use to crimp wires to male contact pins
www.medicon.de
Micro Dissecting Scissors, 3.5 in, 23 mm BladesBiomedical Research Instruments11-2200Only use to cut 3T wires; cutting 10T wires will damage the blade - use the blade of the wire stripper instead
brisurgical.com
PTFE-Coated Stainless Steel Wire, 10T (Bare Diameter .010 in)Sigmund Cohn-Medwire316SS10T
www.sigmundcohn.com
PTFE-Coated Stainless Steel Wire, 3T (Bare Diameter 0.003 in)Sigmund Cohn-Medwire316SS3T
www.sigmundcohn.com
Razor BladeAnyTo strip 1 mm from prongs of bipolar electrode
Relia-Tac Socket Contact Pin, MaleCooper Interconnect220-P02-100See Allied Electronics Cat # 70144761
www.alliedelec.com
Tweezers, High Precision, Serrated, 4 3/4 inElectron Microscopy Sciences78314-00DTo grasp 10T wire firmly while stripping PTFE with smooth tweezers
www.emsdiasum.com
Tweezers, High Precision, Smooth, 4 3/4 inElectron Microscopy Sciences78313-00B
www.emsdiasum.com
Tweezers, Ultra Fine Tips, 4 3/4 inElectron Microscopy Sciences78510-0To strip 1 mm of PTFE from one end of 3T wire; grasp shielded portion with smooth tweezers
www.emsdiasum.com
Wire Stripper, 16-26 AWGAnyUse the blade end to cut micro strips
NameCompanyCatalog NumberComments
Eyelid Surgery
Surgical Instruments (High Quality Stainless Steel)
2 x Dressing Forceps, 4 in SerratedBiomedical Research Instruments30-1205Can be substituted; extra forceps for grasping electrodes/screws outside of surgery tray
brisurgical.com
Dressing Forceps, 3 in SerratedBiomedical Research Instruments30-1200Can be substituted
brisurgical.com
Instrument TrayBiomedical Research Instruments24-1355Can be substituted
brisurgical.com
Knife Handle No. 3, 5 inBiomedical Research Instruments26-1000Can be substituted
brisurgical.com
Micro Dissecting Forceps, 3.5 in, Fine PointsBiomedical Research Instruments10-1630Can be substituted
brisurgical.com
Micro Dissecting Forceps, 3.5 in, Smooth Platform (0.3 x 5 mm)Biomedical Research Instruments10-1720
brisurgical.com
Micro Dissecting Scissors, 3.5 in, Extremely Delicate, 15 mm BladesBiomedical Research Instruments11-2000Can be substituted
brisurgical.com
Plain Splinter Forceps, 3.5 in Biomedical Research Instruments30-1600Can be substituted
brisurgical.com
#10 Stainless Steel Surgical Blade for #3 Handle, SterileAnyCan be substituted
0-80 x 0.125 in Stainless Steel ScrewsPlastics One, Inc.0-80 x 0.125Can be substituted
www.plastics1.com
Alcohol Prep Pads, SterileFisher Scientific22-363-750 [Fisher ScientificCan be substituted
www.fishersci.com
Betadine Povidone-IodinePurdue Frederick Co.6761815101 [Fisher Scientific]Can be substituted
www.fishersci.com
Betadine Povidone-Iodine Prep PadsMoore Medical19-898-946 [Fisher Scientific]Can be substituted
www.fishersci.com
Cotton-Tipped Swabs, AutoclavableAnyTypically 7.6 cm or 15.2 cm length
Drill Bit for Pin Vise, #55 (0.052 in)AnyMetal should resist rusting and corrosion
Gauze Pads, 2 in x 2 inFisher Scientific22-362-178 [Fisher Scientific]Can be substituted
www.fishersci.com
General Purpose Latex/Nitrile/Vinyl GlovesAny
Glass Bead SterilizerAnySterilize instruments between surgeries
Heated Water Therapy Pump w/ Pads x 2GaymarTP-500Can be substituted; separate pumps are recommended - 1 for surgery, 1 for recovery
Hypodermic Needles 26G x 3/8 in, SterileAny
IsofluraneVedcoNDC 50989-150-12Manfacturer can be substituted; veterinary approval may be required
Isoflurane Vaporizer System, Tabletop, Non-RebreathingParkland ScientificV3000PKCan be substituted
www.parklandscientific.com
Jewelers Screwdriver w/ 1.8-2 mm BladeAnyMetal should resist rusting and corrosion
Ortho-Jet BCA Package (Dental Cement)Lang DentalB1334Contains powder (1 lb) and liquid
www.langdental.com
Oxygen Tank with Pressure Regulator, LargeLocal supplier
Porcelain Crucible, High-Form, Glazed, 10 mlCoorsTek, Inc.07-965C [Fisher Scientific]Can be substituted with Fisher FB-965-I Wide-Form Crucible
www.fishersci.com
Puralube Veterinary Ophthalmic Ointment, SterileHenry Schein CompanyNC0144682 [Fisher Scientific]Can be substituted
www.fishersci.com
Quatricide PV-15PharmacalPV-15Antimicrobial disinfectant; can be substituted
www.pharmacal.com
Rat Gas Anesthesia Masks for Stereotaxic Surgery Stoelting Company51610
www.stoeltingco.com
Rat Stereotaxic Apparatus w/ Ear Bars (45 Degree)Any45 degree bars are recommended to prevent damaging eardrums
Roboz Surgical Instrument MilkRoboz SurgicalNC9358575 [Fisher Scientific]Can be substituted; for lubricating instruments during autoclaving
www.fishersci.com
Rodent Hair TrimmerAny
Sodium ChlorideFisher ScientificS641-500 [Fisher Scientific]To make 0.9% saline; reagent grade; USP
www.fishersci.com
Stainless Steel Microspatula (Blade: 0.75 L x 0.18 in. W)Fisher Scientific21-401-15 [Fisher Scientific]Can be substituted
www.fishersci.com
Starrett Pin Vise, 0.000 in - 0.055 inAnyNickel-plated or equivalent recommended to resist rusting and corrosion
Sterile Surgical GlovesAny
Sterilization Wraps, 20 in x 20 in, AutoclavablePropper Manufacturing11-890-8C [Fisher Scientific]Useful for wrapping autoclavable supplies and on sterile field during surgery
www.fishersci.com
Surgical Drape, Sterile/AutoclavableAnyMay need to cut to size for rats
Surgical Gown*Any*If required by IACUC
Surgical MaskAny
Tuberculin Syringes, Sterile, 1.0 mlAny
Weigh ScaleAnyShould have good resolution (in gram units)
NameCompanyCatalog NumberComments
Eyeblink System and Components (assuming 4-rodent system)
5 Channel Commutator x 4Plastics One, Inc.SL2 + 3C
www.plastics1.com
Bipolar Electrode Cable, Dual 305 x 4Plastics One, Inc.305-305 80CM TT2 (C)Provides plug end to bipolar electrode on rat and to commutator; must be modified
www.plastics1.com
Cable, 5 Channel, Shielded, 26 AWG x 4AnyTo fabricate commutator cable; this must be made from scratch
Chamber for Operant Test Box (Inside: 24 H x 23 W x 14 D in) x 4Med-AssociatesCan be substituted; inner dimensions should fit operant test box comfortably, with room for acoustical foam; fit with fan - 55-60 dB
www.med-associates.com
Eyeblink System and SoftwareJSA DesignsN/AProprietary and customized for research lab
Heat Shrink Tubing (3/16 in, 1/4 in, 3/8 in, 1/2 in Diameters)AnyTo protect modified commutator cable soldered ends and splices
Melamine Triple Peak Acoustical Foam w/Black Hypalon (24 x 48 in)McMaster-Carr9162T5Can be substituted; cut to fit 4 housing chambers
www.mcmaster.com
Operant Test Box (Exterior 12.5 L x 10 W x 13.5 in H), Complete x 4Med-AssociatesENV-007 Custom PackageWith stainless steel grid floor and custom top (3 in hole in center for commutator cable)
www.med-associates.com
Oscilloscope (Optional)AnyRecommended minimum specs: 200 MHz analog bandwidth, 1 GS/s real-time sampling, 4 channels; see www.picotech.com
/td>
Piezo Tweeters (Speakers) x 4 (7 x 3 in)MCM Electronics53-805Must match frequency range specifications for eyeblink system (2500 Hz - 25 KHz)
www.mcmelectronics.com
Soldering Station, Solder, Flux, TinnerAnyFor soldering 26 AWG cables to female sockets (that fit male relia-tac contact pins) and bipolar plugs
Stimulus Isolators x 4WPI InternationalA365These units run on 16-9V alkaline batteries; a suitable rechargeable version (A365R) is available
www.wpiinc.com
Tripolar Electrode Cable for SL3C Commutator x 4Plastics One, Inc.335-335 80cm TT3 CProvides plug end to EMG headstage on rat and to commutator; must be modified
www.plastics1.com
USB LED Lights x 4AnyUSB-based lights do not cause electrical "noise" with the EMG signals from the rats
www.plastics1.com
Webcams x 4, Surveillance SoftwareAny
PC Computer Running MS Windows OSAny

Referências

  1. Jones, K. L., Smith, D. W. Recognition of the fetal alcohol syndrome in early infancy. Lancet. 2, 999-1001 (1973).
  2. Stratton, K. R., Howe, C. J., Battaglia, F. C. . Fetal alcohol syndrome: Diagnosis, epidemiology, prevention, and treatment. , (1996).
  3. Streissguth, A. P., Barr, H. M., Martin, D. C., Herman, C. S. Effects of maternal alcohol, nicotine, and caffeine use during pregnancy on infant mental and motor development at eight months. Alcohol Clin Exp Res. 4 (2), 152-164 (1980).
  4. Streissguth, A. P., O'Malley, K. Neuropsychiatric implications and long-term consequences of fetal alcohol spectrum disorders. Semin Clin Neuropsychiatry. 5 (3), 177-190 (2000).
  5. May, P. A., et al. Prevalence and epidemiologic characteristics of FASD from various research methods with an emphasis on recent in-school studies. Dev Disabil Res Rev. 15 (3), 176-192 (2009).
  6. Sowell, E. R., et al. Mapping callosal morphology and cognitive correlates: Effects of heavy prenatal alcohol exposure. Neurology. 57 (2), 235-244 (2001).
  7. Sowell, E. R., et al. Abnormal development of the cerebellar vermis in children prenatally exposed to alcohol: Size reduction in lobules I-V. Alcohol Clin Exp Res. 20 (1), 31-34 (1996).
  8. Autti-Ramo, I., et al. MRI findings in children with school problems who had been exposed prenatally to alcohol. Dev Med Child Neurol. 44 (2), 98-106 (2002).
  9. Hamilton, D. A., Kodituwakku, P., Sutherland, R. J., Savage, D. D. Children with Fetal Alcohol Syndrome are impaired at place learning but not cued-navigation in a virtual Morris water task. Behav Brain Res. 143 (1), 85-94 (2003).
  10. Uecker, A., Nadel, L. Spatial but not object memory impairments in children with fetal alcohol syndrome. Am J Ment Retard. 103 (1), 12-18 (1998).
  11. Uecker, A., Nadel, L. Spatial locations gone awry: object and spatial memory deficits in children with fetal alcohol syndrome. Neuropsychologia. 34 (3), 209-223 (1996).
  12. Goodlett, C. R., Lundahl, K. R. Temporal determinants of neonatal alcohol-induced cerebellar damage and motor performance deficits. Pharmacol Biochem Behav. 55 (4), 531-540 (1996).
  13. Goodlett, C. R., Kelly, S. J., West, J. R. Early postnatal alcohol exposure that produces high blood alcohol levels impairs development of spatial navigation learning. Psychobiol. 15, 64-74 (1987).
  14. Bayer, S. A., Altman, J., Russo, R. J., Zhang, X. Timetables of neurogenesis in the human brain based on experimentally determined patterns in the rat. Neurotoxicol. 14 (1), 83-144 (1993).
  15. Dobbing, J., Sands, J. Quantitative growth and development of human brain. Arch Dis Child. 48 (10), 757-767 (1973).
  16. West, J. R. Fetal alcohol-induced brain damage and the problem of determining temporal vulnerability: A review. Alcohol Drug Res. 7 (5-6), 423-441 (1987).
  17. Zecevic, N., Rakic, P. Differentiation of Purkinje cells and their relationship to other components of developing cerebellar cortex in man. J Comp Neurol. 167, 27-48 (1976).
  18. Rufer, E. S., et al. Adequacy of maternal iron status protects against behavioral, neuroanatomical, and growth deficits in fetal alcohol spectrum disorders. PLoS One. 7 (10), e47499 (2012).
  19. Tran, T. D., Kelly, S. J. Critical periods for ethanol-induced cell loss in the hippocampal formation. Neurotoxicol Teratol. 25 (5), 519-528 (2003).
  20. Pierce, D. R., Goodlett, C. R., West, J. R. Differential neuronal loss following early postnatal alcohol exposure. Teratology. 40 (2), 113-126 (1989).
  21. Tran, T. D., Jackson, H. J., Horn, K. H., Goodlett, C. R. Vitamin E does not protect against neonatal ethanol-induced cerebellar damage or deficits in eyeblink classical conditioning in rats. Alcohol Clin Exp Res. 29 (1), 117-129 (2005).
  22. Goodlett, C. R., Peterson, S. D., Lundahl, K. R., Pearlman, A. D. Binge-like alcohol exposure of neonatal rats via intragastric intubation induces both Purkinje cell loss and cortical astrogliosis. Alcohol Clin Exp Res. 21 (6), 1010-1017 (1997).
  23. Green, J. T., Tran, T. D., Steinmetz, J. E., Goodlett, C. R. Neonatal ethanol produces cerebellar deep nuclear cell loss and correlated disruption of eyeblink conditioning in adult rats. Brain Res. 956, 302-311 (2002).
  24. Cronise, K., Marino, M. D., Tran, T. D., Kelly, S. J. Critical periods for the effects of alcohol exposure on learning in rats. Behav Neurosci. 115 (1), 138-145 (2001).
  25. Tran, T. D., Cronise, K., Marino, M. D., Jenkins, W. J., Kelly, S. J. Critical periods for the effects of alcohol exposure on brain weight, body weight, activity and investigation. Behav Brain Res. 116 (1), 99-110 (2000).
  26. Steinmetz, J. E. Brain substrates of classical eyeblink conditioning: A highly localized but also distributed system. Behav Brain Res. 110 (1-2), 13-24 (2000).
  27. Thompson, R. F. The neurobiology of learning and memory. Science. 233 (4767), 941-947 (1986).
  28. Ivkovich, D., Eckerman, C. O., Krasnegor, N. A., Stanton, M. E., Woodruff-Pak, D. S., Steinmetz, J. E. . Eyeblink classical conditioning: Vol. 1 Applications in humans. , 119-142 (2000).
  29. Woodruff-Pak, D. S., Steinmetz, J. E. . Eyeblink classical conditioning: Volume I - Applications in humans. , (2000).
  30. Woodruff-Pak, D. S., Steinmetz, J. E. . Eyeblink classical conditioning: Volume II - Animal models. , (2000).
  31. Kishimoto, Y., et al. Implicit Memory in Monkeys: Development of a Delay Eyeblink Conditioning System with Parallel Electromyographic and High-Speed Video Measurements. PLoS One. 10 (6), e0129828 (2015).
  32. Chen, L., Bao, S., Lockard, J. M., Kim, J. K., Thompson, R. F. Impaired classical eyeblink conditioning in cerebellar-lesioned and Purkinje cell degeneration (pcd) mutant mice. J Neurosci. 16 (8), 2829-2838 (1996).
  33. Freeman, J. H., Carter, C. S., Stanton, M. E. Early cerebellar lesions impair eyeblink conditioning in developing rats: Differential effects of unilateral lesions on postnatal day 10 or 20. Behav Neurosci. 109 (5), 893-902 (1995).
  34. Gerwig, M., et al. Trace eyeblink conditioning in patients with cerebellar degeneration: Comparison of short and long trace intervals. Exp Brain Res. 187 (1), 85-96 (2008).
  35. LaBar, K. S., Disterhoft, J. F. Conditioning, awareness, and the hippocampus. Hippocampus. 8 (6), 620-626 (1998).
  36. McCormick, D. A., Steinmetz, J. E., Thompson, R. F. Lesions of the inferior olivary complex cause extinction of the classically conditioned eyeblink response. Brain Res. 359 (1-2), 120-130 (1985).
  37. Clark, R. E., Zola, S. Trace eyeblink classical conditioning in the monkey: a nonsurgical method and behavioral analysis. Behav Neurosci. 112 (5), 1062-1068 (1998).
  38. Anderson, B. J., Steinmetz, J. E. Cerebellar and brainstem circuits involved in classical eyeblink conditioning. Rev Neurosci. 5 (3), 251-273 (1994).
  39. Thompson, R. F., Krupa, D. J. Organization of memory traces in the mammalian brain. Annu Rev Neurosci. 17, 519-549 (1994).
  40. Miller, M. J., et al. fMRI of the conscious rabbit during unilateral classical eyeblink conditioning reveals bilateral cerebellar activation. J Neurosci. 23 (37), 11753-11758 (2003).
  41. Geinisman, Y., et al. Remodeling of hippocampal synapses after hippocampus-dependent associative learning. J Comp Neurol. 417 (1), 49-59 (2000).
  42. Ivkovich, D., Stanton, M. E. Effects of early hippocampal lesions on trace, delay, and long-delay eyeblink conditioning in developing rats. Neurobiol Learn Mem. 76 (3), 426-446 (2001).
  43. Moyer, J. R., Deyo, R. A., Disterhoft, J. F. Hippocampectomy disrupts trace eye-blink conditioning in rabbits. Behav Neurosci. 104 (2), 243-252 (1990).
  44. Solomon, P. R., Vander Schaaf, E. R., Thompson, R. F., Weisz, D. J. Hippocampus and trace conditioning of the rabbit's classically conditioned nictitating membrane response. Behav Neurosci. 100 (5), 729-744 (1986).
  45. Kronforst-Collins, M. A., Disterhoft, J. F. Lesions of the caudal area of rabbit medial prefrontal cortex impair trace eyeblink conditioning. Neurobiol Learn Mem. 69 (2), 147-162 (1998).
  46. Weible, A. P., McEchron, M. D., Disterhoft, J. F. Cortical involvement in acquisition and extinction of trace eyeblink conditioning. Behav Neurosci. 114 (6), 1058-1067 (2000).
  47. Thomas, J. D., Tran, T. D. Choline supplementation mitigates trace, but not delay, eyeblink conditioning deficits in rats exposed to alcohol during development. Hippocampus. 22 (3), 619-630 (2012).
  48. West, J. R., Hamre, K. M., Pierce, D. R. Delay in brain growth induced by alcohol in artificially reared rat pups. Alcohol. 1 (3), 213-222 (1984).
  49. Geiger, B. M., Frank, L. E., Caldera-Siu, A. D., Pothos, E. N. Survivable stereotaxic surgery in rodents. J Vis Exp. (20), e880 (2008).
  50. Christian, K. M., Thompson, R. F. Neural substrates of eyeblink conditioning: acquisition and retention. Learn Mem. 10 (6), 427-455 (2003).
  51. Kishimoto, Y., Nakazawa, K., Tonegawa, S., Kirino, Y., Kano, M. Hippocampal CA3 NMDA receptors are crucial for adaptive timing of trace eyeblink conditioned response. J Neurosci. 26 (5), 1562-1570 (2006).
  52. Shors, T. J., et al. Neurogenesis in the adult is involved in the formation of trace memories. Nature. 410 (6826), 372-376 (2001).
  53. Tran, T. D., Stanton, M. E., Goodlett, C. R. Binge-like ethanol exposure during the early postnatal period impairs eyeblink conditioning of short and long CS-US intervals in rats. Dev Psychobiol. 49 (6), 589-605 (2007).
  54. Mizumori, S. J., Yeshenko, O., Gill, K. M., Davis, D. M. Parallel processing across neural systems: Implications for a multiple memory system hypothesis. Neurobiol Learn Mem. 82 (3), 278-298 (2004).
  55. Siegel, J. J., et al. Trace Eyeblink Conditioning in Mice Is Dependent upon the Dorsal Medial Prefrontal Cortex, Cerebellum, and Amygdala: Behavioral Characterization and Functional Circuitry(1,2,3). eNeuro. 2 (4), (2015).
  56. Murawski, N. J., Jablonski, S. A., Brown, K. L., Stanton, M. E. Effects of neonatal alcohol dose and exposure window on long delay and trace eyeblink conditioning in juvenile rats. Behav Brain Res. 236 (1), 307-318 (2013).
  57. Lindquist, D. H. Hippocampal-dependent Pavlovian conditioning in adult rats exposed to binge-like doses of ethanol as neonates. Behav Brain Res. 242, 191-199 (2013).
  58. Ivarsson, M., Svensson, P. Conditioned eyeblink response consists of two distinct components. J Neurophysiol. 83 (2), 796-807 (2000).
  59. Woodruff-Pak, D. S., Lavond, D. G., Thompson, R. F. Trace conditioning: abolished by cerebellar nuclear lesions but not lateral cerebellar cortex aspirations. Brain Res. 348 (2), 249-260 (1985).
  60. Takehara-Nishiuchi, K. The Anatomy and Physiology of Eyeblink Classical Conditioning. Curr Top Behav Neurosci. , (2016).
  61. Mattson, S. N., Schoenfeld, A. M., Riley, E. P. Teratogenic effects of alcohol on brain and behavior. Alcohol Res Health. 25 (3), 185-191 (2001).
  62. Goodfellow, M. J., Abdulla, K. A., Lindquist, D. H. Neonatal Ethanol Exposure Impairs Trace Fear Conditioning and Alters NMDA Receptor Subunit Expression in Adult Male and Female Rats. Alcohol Clin Exp Res. 40 (2), 309-318 (2016).
  63. Beylin, A. V., et al. The role of the hippocampus in trace conditioning: Temporal discontinuity or task difficulty?. Neurobiol Learn Mem. 76 (3), 447-461 (2001).
  64. Port, R. L., Romano, A. G., Steinmetz, J. E., Mikhail, A. A., Patterson, M. M. Retention and acquisition of classical trace conditioned responses by rabbits with hippocampal lesions. Behav Neurosci. 100 (5), 745-752 (1986).
  65. Weiss, C., Bouwmeester, H., Power, J. M., Disterhoft, J. F. Hippocampal lesions prevent trace eyeblink conditioning in the freely moving rat. Behav Brain Res. 99 (2), 123-132 (1999).
  66. Brown, S. M., et al. Eyeblink conditioning deficits indicate timing and cerebellar abnormalities in schizophrenia. Brain Cogn. 58 (1), 94-108 (2005).
  67. Sears, L. L., Steinmetz, J. E. Effects of haloperidol on sensory processing in the hippocampus during classical eyeblink conditioning. Psychopharmacology. 130 (3), 254-260 (1997).
  68. Kronforst-Collins, M. A., Moriearty, P. L., Schmidt, B., Disterhoft, J. F. Metrifonate improves associative learning and retention in aging rabbits. Behav Neurosci. 111 (5), 1031-1040 (1997).
  69. Woodruff-Pak, D. S., Finkbiner, R. G., Sasse, D. K. Eyeblink conditioning discriminates Alzheimer's patients from non-demented aged. Neuroreport. 1 (1), 45-48 (1990).
  70. Oristaglio, J., Romano, A. G., Harvey, J. A. Amphetamine influences conditioned response timing and laterality of anterior cingulate cortex activity during rabbit delay eyeblink conditioning. Neurobiol Learn Mem. 92 (1), 1-18 (2009).
  71. Scavio, M. J., Clift, P. S., Wills, J. C. Posttraining effects of amphetamine, chlorpromazine, ketamine, and scopolamine on the acquisition and extinction of the rabbit's conditioned nictitating membrane response. Behav Neurosci. 106 (6), 900-908 (1992).
  72. Fortier, C. B., et al. Delay discrimination and reversal eyeblink classical conditioning in abstinent chronic alcoholics. Neuropsychology. 22 (2), 196-208 (2008).

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