U. A. F. is supported by the Schram foundation; C.-W. T. P. and W. G. are supported by the Max Planck Society; L.Y. and R.Y. are supported by the Max Planck Society and National Institute of Health (R01MH080047, 1DP1NS096787); A. C. is supported by an FP7 Grant from the European Research Council, the ERANET and I-CORE programs, the Chief Scientist Office of the Israeli Ministry of Health, the Federal Ministry of Education and Research, Roberto and Renata Ruhman, Bruno and Simone Lich, the Nella and Leon Benoziyo Center for Neurological Diseases, the Henry Chanoch Krenter Institute for Biomedical Imaging and Genomics, The Israel Science Foundation the Perlman Family, Adelis, Marc Besen, Pratt and Irving I. Moskowitz foundations; A. A. is supported by the Max Planck Society, the Schram foundation and the Deutsche Forschungsgemeinschaft (DFG). The 3P images were acquired during the Advanced Course on Neuroimaging Techniques at the Max Planck Florida Institute for Neuroscience. The Advanced Course on Neuroimaging Techniques is supported by the Max Planck Society, the Florida State Max Planck Scientific Fellowship program and by the Max Planck Florida Institute Corporation Partnership program. We would like to thank Thorlabs, Coherent and SpectraPhysics for providing support and equipment for the 2P / 3P imaging system during the course. We are also grateful to Henry Haeberle and Melissa Eberle for assistance with the system during the course.

All of the methods described have been approved by the Government of Upper Bavaria (licence 2016_ROB-55.2Vet-2532.Vet_02-16-48) and by the Stanford and Max Planck Florida Institute for Neuroscience Administrative Panels on Laboratory Animal Care.
1. Preparation of the imaging cannula
<ol>
	<li>Hold a precision drill on a drill stand supplied with a movable ruler table.</li>
	<li>Clamp a 3.0 mm diameter stainless steel tube onto the movable ruler table.</li>
	<li>Cut the tube to a 1.6 mm-long metal ring. If the edges of the ring are not blunt after cutting, file out the irregularities.</li>
	<li>Rinse the metal ring and a circular 4 mm-diameter glass coverslip in 100% acetone and leave to dry for &#8776;5 min.</li>
	<li>Place the metal ring and the glass coverslip onto a smooth, even and clean work place, under a stereoscope.</li>
	<li>Place a drop of UV-curing optical adhesive on a smooth surface, such as a Petri dish. Use a needle or a spatula to spread out the adhesive to form a thin (&#60;0.5 mm) layer.</li>
	<li>Use forceps to dip one side of the metal ring into the adhesive. Pay particular attention not to seal the inside of the ring. If this happens, use a needle to break the optical adhesive in the ring.</li>
	<li>Using the stereoscope, position the metal ring at the center of the glass coverslip with the side of the ring covered by adhesive touching the coverslip. A thin ring of adhesive should form at the interface between the metal ring and the coverslip. Avoid any adhesive spreading to the center of the coverslip.</li>
	<li>Turn on the UV-curing LED driver unit and shine light (365 nm) for 1 min. 
	CAUTION: UV light provokes skin burns and is a mutagenic agent. Wear UV-protecting glasses and cover hands and arms with gloves and a lab-coat to avoid skin exposure.</li>
	<li>To cure the adhesive evenly, make sure all sides of the ring are equally illuminated by changing the direction of the light source.</li>
	<li>Let the adhesive harden for at least 2 h, preferably, overnight.</li>
	<li>Firmly hold the cannula from the open end of the metal ring by means of a hemostat. Using a dental drill fitted with a rotating file and working under the stereoscope, file off the excess glass coverslip until flush with the sides of the ring (Figure 1A).</li>
</ol>
2. Implantation of the imaging cannula over the dorsal hippocampus
<ol>
	<li>Preparation of equipment and setup
	<ol>
		<li>Make sure all surgical instruments are clean and sterile. If using a glass bead sterilizer for sterilization, clean the instruments and place them in the sterilizer (set to 250 &#730;C) for 10 min, prior to use. Alternatively, autoclave the instruments before use.</li>
		<li>Prepare all materials required for the surgery, as well as surgical instruments, so that they can be reached readily.</li>
		<li>Make sure there is enough freshly prepared medications such as pain killers or anti-inflammatory drugs.</li>
		<li>Make sure there is enough isoflurane for the whole duration of the surgery (approximately 1 h per surgery).</li>
		<li>Turn on the heating carpet and set it to 37 &#730;C to keep animal temperature stable while under anesthesia.</li>
		<li>Make sure the scavenging system for isoflurane is functioning.</li>
		<li>Open the valve of oxygen flow.</li>
	</ol>
	</li>
	<li>Anesthesia induction, and animal fixation
	<ol>
		<li>Place the mouse in the anesthesia induction chamber at 3% isoflurane in 1 L/min O2 and wait until it loses consciousness. Assess anesthesia using the toe pinch reflex test.</li>
		<li>Weigh the animal.</li>
		<li>Apply anti-inflammatory (Meloxicam, 1mg/Kg) and pain killer (Vetalgin, 200mg/kg) drugs subcutaneously.</li>
		<li>Position the mouse on the heating carpet. Make sure that the animal is not in direct contact with the heating carpet to avoid thermal burns.</li>
		<li>Secure the head to the stereotactic apparatus and position the nose cone to cover the snout. To maintain anesthesia, decrease isoflurane to 1.5-2%. Throughout the surgery, monitor mouse state by visually monitoring breathing and by testing toe pinch reflex. Regulate isoflurane percentage if necessary.</li>
		<li>Apply ophthalmic ointment to the eyes to prevent dehydration and potential blindness. 
		NOTE: For anesthesia and animal medication, alternative methods and drugs are possible. Please, refer to your animal license and the relative literature.</li>
	</ol>
	</li>
	<li>Optic cannula implantation
	<ol>
		<li>Turn on fiber optic light source.</li>
		<li>Remove the hair and disinfect the skin over the mouse head.</li>
		<li>Using scissors and forceps, remove the mouse scalp. Start by making a small cut in the scalp in a position close to lambda. Continue by opening the scalp on the two sides. First move laterally in the direction of ears, then rostrally, in the direction of eye orbits, to form a triangle on the sagittal axis, approximately 4 mm rostral to bregma. Pay attention not to cut too close to ears and eyes, but expose bregma and lambda, as well as parietal bones and the posterior half of frontal bones.</li>
		<li>Apply one drop (&#8776;10 mg) of lidocaine (28.9% v/v in alcohol) to the skull.</li>
		<li>Clear the periosteum and dry the skull using a cotton swab.</li>
		<li>Position the ear bars, to fix the mouse head.</li>
		<li>Make a small craniotomy, using a micro-drill with a 0.5 mm width burr. Position the hole into the frontal bone opposite to the imaged hippocampus, approximately 1.5 mm from the sagittal suture and 2 mm distant from the coronal suture.</li>
		<li>Screw a 0.86 mm-width stainless steel bone screw into the skull hole.</li>
		<li>If necessary, clean the debris and dry the skull.</li>
		<li>Preparation of a mixture of quick adhesive cement
		<ol>
			<li>Using a small spoon (&#8776; 4.5 mm diameter), dispense 1-1.5 level scoops of L-powder into a mixing well.</li>
			<li>Dispense 3-4 drops of Quick Base into the well.</li>
			<li>Dispense 1 drop of Universal Catalyst into the well.</li>
			<li>Stir the mix for 5-10 s using a precision applicator. 
			NOTE: Alternative cements are available. Please refer to their manufacturer&#8217;s instructions.</li>
		</ol>
		</li>
		<li>Use precision applicators to apply quick adhesive cement over the skull, screw and surrounding skin. Let it dry for 30 s to 1 min.</li>
		<li>Use a 3.0 mm diameter trephine drill to make a craniotomy in the parietal bone. Position the hole approximately 1.5 mm distant from the sagittal suture and 2 mm distant from the lambdoid suture.</li>
		<li>Carefully remove the bone flap.</li>
		<li>Check the size of the craniotomy using the cannula to make sure that it fits. Use a 0.5 mm or 0.9 mm width micro-drill to enlarge the craniotomy if necessary.</li>
		<li>Remove the meninges using Dumont forceps.</li>
		<li>Ablate cortical matter, to reach the external capsule. Use a 0.9 mm diameter (19 gauge) blunt needle connected to a vacuum pump. Irrigate with saline to avoid dehydration of the exposed tissue and to wash away residual blood after bleeding is resolved. Suck cortical tissue slowly, &#8776;50-100 &#181;m at a time, until cortex detaches from the capsule, exposing the fibers of the cingulum or the corpus callosum. Change the needle frequently, to prevent clogging.</li>
		<li>Fibers extend mainly in three directions (Figure 1B). Carefully peel the dorsal fibers until the deepest fibers (alveus of the hippocampus) are exposed.</li>
		<li>Rinse the tissue with saline. Use thin forceps to dip the bottom cannula into saline and position it over the skull hole. Cannula and tissue have to be sealed by saline to avoid trapping air bubbles between the cannula and the tissue.</li>
		<li>Push the cannula into the skull (Figure 1C) until the glass coverslip is in contact with the fibers.</li>
		<li>Dry the skull well using absorption triangles, cotton swabs and/or the vacuum pump.</li>
		<li>Preparation of a mixture of quick adhesive cement (refer to step 2.3.10).</li>
		<li>Use precision applicators to apply quick adhesive cement over the skull. Apply adhesive also on the rim of the cannula. Be careful not to let the adhesive run into the cannula. Let it dry for 30 s to 1 min.</li>
		<li>Use a stereotaxic arm to position a head holder plate over the cannula, in contact with the skull.</li>
		<li>Preparation of a mixture of dental acrylic
		<ol>
			<li>Using a spoon (&#8776;9 mm diameter), dispense 1 level scoop (1 part) of powder into a mixing well.</li>
			<li>Dispense 2-3 parts of liquid in the same well. Cover the whole powder with the liquid.</li>
			<li>Stir for &#8776;1 min using a spatula. 
			NOTE: Alternative acrylics are available. Please refer to their manufacturer&#8217;s instructions.</li>
		</ol>
		</li>
		<li>Use a spatula or a precision applicator to apply acrylic across the cranium. Cover the entire exposed skull, the screw and the open skin with dental acrylic. This makes the preparation stable. Do not let acrylic run down the neck, ears and eyes.</li>
		<li>Let the acrylic dry and harden for about 15 min.</li>
		<li>Apply a removable adhesive film onto the head holder plate, to prevent debris from entering the cannula. It is recommended that the film size matches that of the plate.</li>
		<li>Turn off isoflurane flow, remove the animal from stereotactic apparatus and position it on a heating plate to maintain physiological body temperature while it wakes up from anesthesia.</li>
		<li>Monitor the animal until it has regained sufficient consciousness to maintain sternal recumbency.</li>
		<li>Return the animal which has undergone surgery to the company of other animals only when fully recovered.</li>
	</ol>
	</li>
</ol>
3. Postoperative care
<ol>
	<li>Check the status of the mouse for 2 days following surgery, by monitoring the weight and general behavior.</li>
	<li>Apply anti-inflammatory (Meloxicam, 1mg/Kg) and pain killer (Vetalgin, 200mg/kg) drugs subcutaneously for 2 days following surgery 
	NOTE: Alternative monitoring procedures, drugs and dosages are possible for postoperative care. Please, refer to your animal license and the relative literature.</li>
</ol>
4. Preparation of the imaging session
<ol>
	<li>Turn on the imaging setup in advance and let the laser to warm up and stabilize, if necessary.</li>
	<li>Anesthetize the mouse (refer to step 2.2.1).</li>
	<li>Use forceps to carefully remove the adhesive film from the head holder plate. Hold the mouse in a hand and the head holder plate with the fingers. Remove the film gently, to avoid damaging the preparation.</li>
	<li>Position the mouse under the microscope, over the heating carpet and secure the head plate to the holder (Figure 1D).</li>
	<li>Position the nose cone to cover the snout and decrease isoflurane to 1.5-2%.</li>
	<li>Apply ophthalmic ointment to the mouse eyes.</li>
	<li>Clean the imaging cannula by rinsing with deionized water. Use a syringe and a thin needle to drop water into the cannula and a vacuum pump to remove it.</li>
</ol>
5. Imaging session
<ol>
	<li>Use low magnification, long working distance objectives to visually check the cannula for residual water, dirt, integrity and the presence of fluorescence.</li>
	<li>Align the cannula to the optic axis by adjusting the angles of the head holder arms.</li>
	<li>Switch to the 25X 1.0 NA, 4 mm WD or the 40X 0.8 NA, 3 mm WD, water immersion objectives. Add enough deionized water to fill the cannula and maintain excess water on top of the cannula. Avoid the formation of air bubbles.</li>
	<li>Use 2P excitation and image fluorescent signals. 
	NOTE: The imaging protocol is highly dependent on the time and spatial scales to be imaged. Please refer to the sections representative results and discussion for details about the imaging settings we have used to produce the images shown in this article.</li>
</ol>

The authors have nothing to disclose.

Here, a procedure for repeated 2P imaging of the dorsal CA1 in live mice is described. After the surgery, the mouse usually recovers within 2 days. The procedure induces minimal astrogliosis26,43. Hemorrhage and edema which might follow the surgery are usually re-adsorbed within 10 to 14 days. Generally, from 14 days post-implantation onwards the preparation is sufficiently clear to perform intravital imaging. The success of the surgery does not depend on working in a sterile environment. However, it is crucial to maintain a high level of hygiene, to avoid complications due to surgery-associated infections. This is obtained by meticulously cleaning the surgical instruments before and after the surgery and by heat-sterilizing them immediately prior to each usage (step 2.1.1). The optic cannula is kept into a clean, sterilized container and rinsed with sterile saline just before the implantation. Performing common surgical practices of hands disinfection and cleaning of the surgical station is also very important. The preparation remains stable and allows cellular and subcellular resolution imaging for several weeks26,35.
Critical steps, modifications and troubleshooting. 
It is important to peel the external capsule until the deepest fibers are exposed. Failure to expose the alveus might result in the inability to focus on the soma of PNs, or in reduced resolution imaging dendritic spines, when using commercial objectives with 3- or 4-mm WD. To this aim, it is useful to ablate the neocortex very slowly using a 0.9 mm diameter needle and then switch to a 0.3-0.5 mm diameter (24-29 gauge) needle for a finer control of suction when removing the most dorsal fibers. Alternatively, fine forceps may be used to remove the remaining cortex after fiber exposure36.
Bleeding during surgery can be problematic, as blood obstructs the view. Waiting for the clot to form and then rinsing with saline to wash away residual blood is recommended. Repeat as necessary.
A snug fit between the cannula and the craniotomy helps increase the stability of the preparation by keeping the cannula in place before application of the cement, especially if the outer rim of the cannula is flush with the skull. Since the sizes of the trephine drill and the cannula are matched, a loose fit can arise because of irregularities on the side of the cannula - which require slightly larger craniotomies to fit (see step 2.3.14) - or from an irregular craniotomy. Any cannula irregularities must be filed off (steps 1.3 and 1.12) and the trephine must be held perpendicular to the skull until the craniotomy is completed (step 2.3.12). Removing the trephine from the skull before the craniotomy is completed may result in irregular craniotomies.
Limitations-Invasiveness and stability of the preparation. 
It is difficult to evaluate the effect of cortical ablation as it is arduous to precisely define the areas affected directly and indirectly. In general, the surgery removes part of the parietal cortex and part of the visual and hindlimb sensory cortex21. The ablated cortex does not directly project to the hippocampus and hippocampal tissue is neither touched nor injured. Importantly, it has been shown that implantation of an imaging cannula does not grossly alter hippocampal function and specifically hippocampal-dependent learning21,36,37,38,39. Still, it would be important to quantify to what extent both the cannula and the external part of the implant (head holder plate and dental acrylic cap) are chronic stressors by assessing corticosterone blood levels and adrenal gland weight in comparison to unimplanted mice.
The preparation generally remains stable from weeks to months26. In the long term, skin and bone growth tend to displace the acrylic cap and to increase the instability of the imaging preparation.
Optical limitations. 
Conventional 2P microscopy allows imaging up to about 1 mm deep into neocortical tissue40,41. Consistent with this, it is possible to image dendrites and dendritic spines located in the SR (Figure&#160;2D-F) or SLM36. However, imaging through a cannula poses limitations to the effective NA. To achieve the maximum resolution, the diameter and depth of the imaging cannulas should be matched to the imaging NA, as smaller diameters and longer depths will clip light of high NA objectives. For instance, when imaging with a 1.0 NA water immersion objective through a 1.6 mm long cannula, a 3.65 mm inner diameter is needed to keep the full NA. However, using a cannula of this diameter will increase the compression on the hippocampus and might affect the health of the tissue, for this reason, we use a cannula with a smaller diameter. When imaging with a 0.8 NA water immersion objective through a 1.6 mm long cannula, an inner diameter of 2.5 mm would be sufficient to keep the full NA. However, 0.8 NA water immersion objectives have a shorter WD (3 mm in our case), which can prevent from focusing at the SP.
These calculations apply to the center of the field of view at the bottom of the cannula. However, moving the imaging field of view sidewise - closer to the edges of the cannula - or focusing deeper into the tissue - farther from the glass surface of the cannula - further decreases the effective NA at the focal plane and thus reduces resolution. This will lead to non-homogenous resolution across the different volumes of imaged tissue and can be a concern for quantitative imaging at subcellular resolution, especially when using super-resolution techniques such as 2P-STED microscopy42. These issues are less important when imaging at cellular resolution.
Tissue motion. 
Motion within the tissue - originating from breathing and heartbeat in anesthetized animals - tends to become more severe with increased distance from the imaging cannula. This is possibly because the imaging cannula applies mechanical pressure to the brain thus counteracting some of the motion in the vicinity of the cannula (similarly to neocortical preparations). Thus, although imaging of dendritic spines is possible in SR and SLM, in our hands, it is most robust dorsal to the SO up to &#8776;200 &#181;m from the surface of the cannula. To compensate for motion, we use resonant scanners and offline averaging. Several images (4 to 6 repetitions) are acquired per image plane of a z-stack at the maximum available speed (30 frames/s). All the repetitions for each z-plane are then deconvolved (using the commercial software, AutoQuant), registered (using ImageJ) and averaged into a single image26. For imaging of somata, motion is often negligible upon anesthesia35 and two averages are often sufficient to compensate for motion artifacts.
Future applications or directions of the method. 
The preparation can be combined with micro-endoscopes26,43. Micro-endoscopes are rigid optic probes which use gradient refractive index (GRIN) microlenses to guide light to and from deep tissue18. The use of micro-endoscopes allows cannulas of smaller diameters or even no cannulas at all. However, commercial micro-endoscopes are less well corrected for optical aberrations and have lower NA than commercial objectives. Current probes reach lateral and axial resolutions of &#8776;0.6-1 &#181;m, &#8776;10-12 &#181;m, respectively17,18,44. The use of micro-endoscopes also enables the combination of this preparation with head-mounted integrated widefield microscopes45,46,47.
The method lends itself also to use in non-anesthetized mice, and it has been used to investigate cellular activity using Ca2+ sensors in awake head-fixed mice21,37,48,49. In these cases, due to the fast time scales of the fluorescence changes, it is advisable to implement line registration50. It is also possible to adapt the preparation for imaging of other hippocampal sub-regions such as the dentate gyrus (DG)39,51,52. Combining this preparation with 3P excitation53,54 with 1 MHz frequency pulsed laser tuned to 1400 nm, we were able to image deeper into the hippocampal formation reaching the molecular layer, granule cell layer and the hilus of the DG (Figure 4) without removing the overlaying CA1.
In conclusion, we present a method that provides optical access to the dorsal hippocampus and allows longitudinal and correlative studies of the dynamics of hippocampal structure and activity. This technique extends the possibilities of analysis of hippocampal function under physiological and pathological conditions.

In mammals, the hippocampus is a key brain region for the encoding and recall of episodic memories as well as for spatial navigation1,2,3,4. For this reason, the hippocampus has been - and still is - a very important model to study the basic mechanisms that allow the brain to encode and recall memories5,6,7 or to navigate in an environment8,9 collecting rewards and avoiding dangers. In addition, the hippocampal formation is one of the brain regions where new neurons are generated throughout the life of rodents10,11 and, possibly, of humans12,13. Finally, degeneration or impairment of the hippocampal formation are associated with neurological and psychiatric disorders, including Alzheimer&#8217;s disease14.
In mice, the hippocampus is located approximately 1 mm below the brain surface15. Its position has prevented optic access in the intact brain and consequently, longitudinal studies of hippocampal dynamics have relied mostly on magnetic resonance (MR) imaging, electrophysiology, and ex vivo imaging analyses. MR imaging methods allow tracking of biological processes (e.g., gene expression changes16) in the same animal over multiple days, but lack the spatial resolution to discriminate single neurons. Classic in vivo electrophysiological techniques offer very high temporal resolution and exquisite sensitivity to changes in membrane potential. However, they have a limited spatial resolution and they lack the ability to reliably track the same cells over longer time periods. Optical imaging allows more diverse processes to be studied by virtue of its high temporal and spatial resolutions. However, ex vivo imaging only provides snapshots of ongoing processes, and thus it is not suitable for longitudinal studies during which the animals learn and recall information.
In vivo optical imaging combines some advantages of MR imaging and electrophysiology with those of optical imaging. Therefore, it is very well suited for longitudinal and correlative analyses of mouse brain dynamics and behavior. This is relevant in studies of biological processes with very fast (milliseconds to seconds) or very slow (days to weeks) time scales. Examples for such processes that are relevant for neuroscience are membrane voltage dynamics, Ca2+ transients, cellular plasticity and structural changes, which are all believed to be very important for memory formation and recall. Different methods have extended in vivo imaging to the dorsal hippocampus18,19,20,21,22. Acute preparations have allowed the tracking of pyramidal neuron (PN) activity as well as their dendrites and dendritic spines for several hours20,22. This temporal timeframe, however, does not allow long-term structural changes, which might underlie incremental learning, to be studied. Chronic preparations - in combination with micro-endoscopes23,24 or with long working distance (WD) standard microscope objectives21 - have enabled repeated imaging of the dorsal hippocampus over several weeks.
Here, we describe a chronic preparation that provides recurrent optic access to the CA1 sub-field of the dorsal hippocampus of living mice using a permanently inserted imaging cannula. This preparation allows repeated access to the CA1 without functional disturbance and is suitable for intravital two-photon (2P) or wide-field epifluorescence imaging. Two examples of 2P deep brain chronic imaging in the dorsal CA1 of live mice are detailed: longitudinal imaging of dendritic structure and dendritic spine dynamics and longitudinal imaging of activity-evoked plasticity. The salient advantages and limitations of the technique are discussed.

<table>
	<tbody>
		<tr>
			<td>Professional drill/grinder IBS/E</td>
			<td>Proxxon GmbH</td>
			<td>28481</td>
			<td>Pecision drill</td>
		</tr>
		<tr>
			<td>MICROMOT drill stand MB 200</td>
			<td>Proxxon GmbH</td>
			<td>28600</td>
			<td>Movable ruler table</td>
		</tr>
		<tr>
			<td>MICRO compound table KT 70</td>
			<td>Proxxon GmbH</td>
			<td>27100</td>
			<td>Movable ruler table</td>
		</tr>
		<tr>
			<td>Machine vice MS 4</td>
			<td>Proxxon GmbH</td>
			<td>28132</td>
			<td>Movable ruler table</td>
		</tr>
		<tr>
			<td>Stainless steel tube &#216; 3,0 x 0,25 mm (Inner &#216; 2,5 mm ) L = 500 mm</td>
			<td>Sawade</td>
			<td>R00303</td>
			<td>Stainless steel tube for the cannula metal ring</td>
		</tr>
		<tr>
			<td>Microscope Cover glass (4 mm round)</td>
			<td>Engelbrecht Medizin and Labortechnik</td>
			<td></td>
			<td>Glass coverslips for the cannula glass</td>
		</tr>
		<tr>
			<td>Schlusselfeilensatz 6-tgl. Im Blechetui</td>
			<td>Hoffmann Group</td>
			<td>713750 160</td>
			<td>Manual files</td>
		</tr>
		<tr>
			<td>Pr&#228;zisions-Nadelfeile Gesamtl&#228;nge 140 mm 4</td>
			<td>Hoffmann Group</td>
			<td>527230 4</td>
			<td>Manual files</td>
		</tr>
		<tr>
			<td>UV-Curing Optical Adhesives</td>
			<td>Thorlabs</td>
			<td>NOA81</td>
			<td>UV-curing adhesive</td>
		</tr>
		<tr>
			<td>UV Curing LED System, 365 nm</td>
			<td>Thorlabs</td>
			<td>CS2010</td>
			<td>UV-curing LED driver unit</td>
		</tr>
		<tr>
			<td>Stemi 305</td>
			<td>Zeiss</td>
			<td></td>
			<td>Stereoscope</td>
		</tr>
		<tr>
			<td>Presto II</td>
			<td>NSK-Nakanishi Germany</td>
			<td>Z307015</td>
			<td>Dental drill</td>
		</tr>
		<tr>
			<td>Diamantbohrer FG (5 St.), Zylinder flach, 837-014 fein</td>
			<td>MF Dental</td>
			<td>F837.014.FG</td>
			<td>Files for the dental drill</td>
		</tr>
		<tr>
			<td>Diamantbohrer FG (5 St.), Zylinder flach, 837-014 grob</td>
			<td>MF Dental</td>
			<td>G837.014.FG</td>
			<td>Files for the dental drill</td>
		</tr>
		<tr>
			<td>Graefe Forceps - Straight / Serrated</td>
			<td>Fine Science Tools</td>
			<td>11050-10</td>
			<td>Forceps for the surgery</td>
		</tr>
		<tr>
			<td>Burrs for Micro Drill</td>
			<td>Fine Science Tools</td>
			<td>19008-05</td>
			<td>0.5 mm width burr for the micro-drill</td>
		</tr>
		<tr>
			<td>Burrs for Micro Drill</td>
			<td>Fine Science Tools</td>
			<td>19008-09</td>
			<td>0.9 mm width burr for the micro-drill</td>
		</tr>
		<tr>
			<td>MicroMotor mit Handst&#252;ck</td>
			<td>DentaTec</td>
			<td>MM11</td>
			<td>Micro-drill for the craniotomy</td>
		</tr>
		<tr>
			<td>Dumont #3 Forceps</td>
			<td>Fine Science Tools</td>
			<td>11231-30</td>
			<td>Dumont forceps for the surgery</td>
		</tr>
		<tr>
			<td>Fine Scissors - ToughCut</td>
			<td>Fine Science Tools</td>
			<td>14058-09</td>
			<td>Scissors for the surgery</td>
		</tr>
		<tr>
			<td>Trephine</td>
			<td>MW Dental</td>
			<td>229-020</td>
			<td>Trephine drill - 3.0 mm diameter; for the micro-drill</td>
		</tr>
		<tr>
			<td>Stainless Steel Self-Tapping Bone Screws</td>
			<td>Fine Science Tools</td>
			<td>19010-10</td>
			<td>0.86 mm width bone screws</td>
		</tr>
		<tr>
			<td>Stereotaxic apparatus</td>
			<td>Kopf</td>
			<td></td>
			<td>Stereotaxic apparatus</td>
		</tr>
		<tr>
			<td>3-D-Gelenkarm</td>
			<td>Hoffmann Group</td>
			<td>442114</td>
			<td>Stereotaxic arm and plate holder</td>
		</tr>
		<tr>
			<td>Aufnahme 2SM</td>
			<td>Hoffmann Group</td>
			<td>442100 2SM</td>
			<td>Stereotaxic arm and plate holder</td>
		</tr>
		<tr>
			<td>Hot Bead Sterilizers</td>
			<td>Fine Science Tools</td>
			<td>18000-45</td>
			<td>Glass beads sterilizer</td>
		</tr>
		<tr>
			<td>Isofluran CP, Flasche 250 ml</td>
			<td>Henry Schein VET GmbH</td>
			<td>798932</td>
			<td>Liquid isoflurane for anesthesia</td>
		</tr>
		<tr>
			<td>Harvard Apparatus Isoflurane Funnel-Fill Vaporizer</td>
			<td>Harvard Apparatus GmbH</td>
			<td>34-1040</td>
			<td>Isoflurane vaporizer</td>
		</tr>
		<tr>
			<td>Lab Active Scavenger</td>
			<td>Gropper Medizintechnik</td>
			<td>UV17014</td>
			<td>Isoflurane scavenger system</td>
		</tr>
		<tr>
			<td>Metacam 0,5% Injektionslsg. (Hund / Katze), Flasche 20 ml</td>
			<td>Henry Schein VET GmbH</td>
			<td>798566</td>
			<td>Meloxicam, anti-inflammatory</td>
		</tr>
		<tr>
			<td>Vetalgin 500 mg/ml</td>
			<td>MSD Tiergesundheit</td>
			<td></td>
			<td>Vetalgin, pain killer</td>
		</tr>
		<tr>
			<td>CMA 450 Temperature Controller</td>
			<td>Hugo Sachs Elektronik - Harvard Apparatus GmbH</td>
			<td>8003770</td>
			<td>Heating blanket</td>
		</tr>
		<tr>
			<td>Bepanthen Augen- und Nasensalbe</td>
			<td>Bayer AG</td>
			<td></td>
			<td>Ophtalmic ointment</td>
		</tr>
		<tr>
			<td>KL 1500 LCD</td>
			<td>Schott</td>
			<td></td>
			<td>Fiber optic light source</td>
		</tr>
		<tr>
			<td>Xylocain Pumpspray</td>
			<td>AstraZeneca GmbH</td>
			<td></td>
			<td>Lidocain, local anesthetic</td>
		</tr>
		<tr>
			<td>Absorption Triangles - Unmounted</td>
			<td>Fine Science Tools</td>
			<td>18105-03</td>
			<td>Absorption triangles for the surgery</td>
		</tr>
		<tr>
			<td>Parkell C&#38;B Metabond clear powder L</td>
			<td>Hofmeester dental</td>
			<td>013622</td>
			<td>Quick adhesive cement</td>
		</tr>
		<tr>
			<td>Parkell C&#38;B Metabond Quick Base B</td>
			<td>Hofmeester dental</td>
			<td>013621</td>
			<td>Quick adhesive cement</td>
		</tr>
		<tr>
			<td>Parkell C&#38;B Metabond Universal Catalyst C</td>
			<td>Hofmeester dental</td>
			<td>013620</td>
			<td>Quick adhesive cement</td>
		</tr>
		<tr>
			<td>Adjustable Precision Applicator Brushes</td>
			<td>Parkell</td>
			<td>S379</td>
			<td>Precision applicators for the surgery</td>
		</tr>
		<tr>
			<td>Blunt needles 0.9x23 mm</td>
			<td>Dentina</td>
			<td>0441324</td>
			<td>Blunt needles</td>
		</tr>
		<tr>
			<td>Blunt needles 0.5x42 mm</td>
			<td>Dentina</td>
			<td>0452155</td>
			<td>Blunt needles</td>
		</tr>
		<tr>
			<td>Blunt needles 0.3x23 mm</td>
			<td>Dentina</td>
			<td>0553532</td>
			<td>Blunt needles</td>
		</tr>
		<tr>
			<td>Kallocryl A/C</td>
			<td>Speiko</td>
			<td>1615</td>
			<td>Acrylic liquid component</td>
		</tr>
		<tr>
			<td>Kallocryl</td>
			<td>Speiko</td>
			<td>1609</td>
			<td>Acrylic powder</td>
		</tr>
		<tr>
			<td>Hydrofilm transparent roll</td>
			<td>Hartmann</td>
			<td></td>
			<td>Adhesive film</td>
		</tr>
		<tr>
			<td>Head plates</td>
			<td>Custom made</td>
			<td></td>
			<td>30 mm x 10 mm size; 8 mm diameter hole, titanium</td>
		</tr>
		<tr>
			<td>Head plate clamp</td>
			<td>Custom made</td>
			<td></td>
			<td>Head plate holder</td>
		</tr>
		<tr>
			<td>Pedestal post holders</td>
			<td>Thorlabs</td>
			<td>PH20E/M</td>
			<td>Head plate holder</td>
		</tr>
		<tr>
			<td>Stainless steel post</td>
			<td>Thorlabs</td>
			<td>TR30/M</td>
			<td>Head plate holder</td>
		</tr>
		<tr>
			<td>Stainless steel post</td>
			<td>Thorlabs</td>
			<td>TR75/M</td>
			<td>Head plate holder</td>
		</tr>
		<tr>
			<td>Stainless steel post</td>
			<td>Thorlabs</td>
			<td>TR150/M</td>
			<td>Head plate holder</td>
		</tr>
		<tr>
			<td>Post connector clamps</td>
			<td>Custom made</td>
			<td></td>
			<td>Head plate holder</td>
		</tr>
		<tr>
			<td>Aluminum Breadboard, 300 mm x 450 mm x 12.7 mm, M6 Taps</td>
			<td>Thorlabs</td>
			<td>MB3045/M</td>
			<td>Microscope stage</td>
		</tr>
		<tr>
			<td>7&#34; x 4&#34; Lab Jack</td>
			<td>Thorlabs</td>
			<td>L490/M</td>
			<td>Microscope stage</td>
		</tr>
		<tr>
			<td>Low profile face mask small mice</td>
			<td>Emka Technologies</td>
			<td>VetFlo-0801</td>
			<td>Anesthesia facemask holder</td>
		</tr>
		<tr>
			<td>RS4000 Tuned Damped Top Performance Optical Table</td>
			<td>Newport</td>
			<td></td>
			<td>Floating table</td>
		</tr>
		<tr>
			<td>S-2000A Top Performance Pneumatic Vibration Isolators with Automatic Re-Leveling</td>
			<td>Newport</td>
			<td></td>
			<td>Floating table</td>
		</tr>
		<tr>
			<td>Power Meter Model 1918-R</td>
			<td>Newport</td>
			<td></td>
			<td>Power meter</td>
		</tr>
		<tr>
			<td>X-Cite 120Q</td>
			<td>Excelitas Technologies</td>
			<td></td>
			<td>Fluorescence lamp</td>
		</tr>
		<tr>
			<td>Two-photon microscope</td>
			<td>Bruker</td>
			<td>Ultima IV</td>
			<td>Two-photon microscopes</td>
		</tr>
		<tr>
			<td>Two-photon microscope</td>
			<td>Thorlabs</td>
			<td>Bergamo</td>
			<td>Two-photon microscopes</td>
		</tr>
		<tr>
			<td>Plan N 4x/0.10 &#8734;/-/FN22</td>
			<td>Olympus</td>
			<td></td>
			<td>Objectives</td>
		</tr>
		<tr>
			<td>Plan N 10x/0.25 &#8734;/-/FN22</td>
			<td>Olympus</td>
			<td></td>
			<td>Objectives</td>
		</tr>
		<tr>
			<td>LMPlan FLN 20x/0.40 &#8734;/-/FN26.5</td>
			<td>Olympus</td>
			<td></td>
			<td>Objectives</td>
		</tr>
		<tr>
			<td>XLPlan N 25x/1.00 SVMP &#8734;/0-0.23/FN18</td>
			<td>Olympus</td>
			<td></td>
			<td>Objectives</td>
		</tr>
		<tr>
			<td>Ultafast tunable laser for 2P excitation</td>
			<td>Spectraphysics</td>
			<td>Mai Tai Deep See</td>
			<td>Excitaiton lasers</td>
		</tr>
		<tr>
			<td>Ultafast tunable laser for 2P excitation</td>
			<td>Spectraphysics</td>
			<td>InSight DS+ Dual beam</td>
			<td>Excitaiton lasers</td>
		</tr>
		<tr>
			<td>Ultafast tunable laser for 3P excitation</td>
			<td>Coherent</td>
			<td>Monaco</td>
			<td>Excitaiton lasers</td>
		</tr>
	</tbody>
</table>

longitudinal two-photon imaging of dorsal hippocampal ca1 in live mice

Two-photon microscopy is a fundamental tool for neuroscience as it permits investigation of the brain of live animals at spatial scales ranging from subcellular to network levels and at temporal scales from milliseconds to weeks. In addition, two-photon imaging can be combined with a variety of behavioral tasks to explore the causal relationships between brain function and behavior. However, in mammals, limited penetration and scattering of light have limited two-photon intravital imaging mostly to superficial brain regions, thus precluding longitudinal investigation of deep-brain areas such as the hippocampus. The hippocampus is involved in spatial navigation and episodic memory and is a long-standing model used to study cellular as well as cognitive processes important for learning and recall, both in health and disease. Here, a preparation that enables chronic optical access to the dorsal hippocampus in living mice is detailed. This preparation can be combined with two-photon optical imaging at cellular and subcellular resolution in head fixed, anesthetized live mice over several weeks. These techniques enable repeated imaging of neuronal structure or activity-evoked plasticity in tens to hundreds of neurons in the dorsal hippocampal CA1. Furthermore, this chronic preparation can be used in combination with other techniques such as micro-endoscopy, head-mounted wide field microscopy or three-photon microscopy, thus greatly expanding the toolbox to study cellular and network processes involved in learning and memory.

Since the cannula is placed just dorsal to CA1, the dorsal aspect of the CA1 is more proximal to the microscope if compared to the ventral one. The alveus is the most proximal structure followed in order by stratum oriens (SO), stratum pyramidale (SP), stratum radiatum (SR) and stratum lacunosum moleculare (SLM), the most distal layer (Figures 1B, C). Longitudinal 2P imaging of neuronal structure with subcellular resolution and of activity-evoked plasticity with cellular resolution are presented as representative results. To excite the fluorophores green fluorescent protein (GFP), d2Venus and TurboFP635, a femtosecond pulsed Ti:Sapphire laser tuned to 920 nm is used and the average laser power is adjusted to 5-25 mW at the sample. The different emission wavelengths are separated using emission filters and different photomultiplier tubes.
Longitudinal imaging of dendritic structure and dendritic spines dynamics. 
To sparsely label hippocampal PNs and visualize their structure, a Thy1-GFP transgenic mouse line (M line) is used. Thy1-GFP mice express cytoplasmic enhanced GFP under the control of the Thy1 promoter in a sparse, random population of PNs25. Generally, the major axis of CA1 PNs is roughly perpendicular to the XY-imaging plane (Figures 1B, Figure 2A and Supplementary Movie 1). Basal dendrites extend in the SO, from the soma towards the cannula, whereas apical and apical tuft dendrites extend distally to the cannula, in the opposite direction (Supplementary Movie 1). Since the preparation leaves the deepest fibers of the alveus intact, a few fluorescent fibers traversing the field of view, just beneath the cannula, should be visible (Figure 2A and Movie 1). The preparation allows imaging of PN dendrites with spine resolution (Figure 2 A-C). To image dendrites and dendritic spines, a 25X 1.0 NA, 4 mm WD, water immersion commercial objective lens is used.
For longitudinal tracking, several brain regions within the field of view of the cannula are defined during the first imaging session. Each region corresponds to an area of approximately 240 x 240 &#181;m and contains between 1 and 7 dendritic segments (Figure 2B). These regions are manually mapped to a low magnification three-dimensional stack showing the pattern of GFP expression in the volume below the imaging cannula (Figure 2A). Then, 1 &#181;m z-step image stacks of CA1 PN basal dendrites are acquired at different time intervals (from 24 h to 3 days) for up to about 14 days (Figure 2C). Longer imaging durations and intervals are possible26. Each imaging session lasts approximately 60 to 90 min. Although most images are of dendritic spines in the SO, it is also possible to image dendritic spines in the oblique dendrites of SR (Figures 2D-F). In addition to spine density, this method enables the study of spine dynamics by quantifying their survival, gain and loss rates26,27,28,29,30,31,32. To score and track dendritic spines over time (Figure 2C), a custom MATLAB interface is used. This enables the alignment of the image stacks acquired at different time points and supports manual labeling of dendrites and spines while tracking dendritic lengths and spine positions over time26. Importantly, this method can be used to distinguish (per each time point, excluding the first one) between pre-existing and newborn dendritic spines. This is important as the different classes of dendritic spines are thought to have different roles in memory acquisition and retention33.
Longitudinal imaging of activity-evoked plasticity.
To image activity-evoked plasticity in CA1 PNs, the dorsal CA1 hippocampal area is injected with a viral vector expressing green fluorescent destabilized d2Venus via an enhanced form of the synaptic activity-responsive element (E-SARE) within the Arc enhancer/promoter and red fluorescent TurboFP635 via the ePGK promoter34. This allows for imaging levels of activity-evoked plasticity of hundreds of CA1 PNs in each animal35. Given the very dense labeling of PNs, it is generally not possible to resolve the dendrites of CA1 PNs (Supplementary Movie 2).
To image the somata of CA1 PNs, a 40X 0.8 NA, 3 mm WD, water immersion objective lens is used. For longitudinal tracking, 1 to 9 brain regions are defined per mouse during the first imaging session. Each region corresponds to an area of approximately 300 x 300 &#181;m and contains between 50 and 150 cells (Figure 3A). These regions are manually mapped to local tissue landmarks visible at a lower magnification. Then, 3 &#181;m z-step image stacks are acquired, which encompass the SP of CA1 PNs (Figure 3A and Supplementary Movie 2) at different time intervals (from 24 h to 6 days) for up to about 30 days. Each imaging session lasts approximately 60 to 90 min. E-SARE activation peaks 6 to 8 h after an exposure to a new or enriched environment (EE, Figure 3B) and decays over the course of a few days. Thus, we generally image 6 to 8 h after experience and allow for 5 days between imaging sessions35.
To quantify d2Venus and TurboFP635 fluorescence values, a circular region-of-interest 4.64 &#181;m in diameter is drawn, which is smaller than a neural cell body, centered to the cell soma. We then progress to the next time point, score the soma of the same cell in the same way, and iterate this procedure for all time points and all visible cells in the longitudinal dataset. The mean value of each neuron&#8217;s (activity-dependent) d2Venus emission is normalized by its mean (activity-independent) TurboFP635 emission. This method enables the investigation of long-term dynamics of ensemble plasticity of CA1 PNs35 (Figure 3C).
<img alt="Figure 1" class="xfigimg" src="/files/ftp_upload/59598/59598fig1.jpg" /> 
Figure 1: Preparation for in vivo deep brain optical imaging. (A). Top (left) and side (right) views of example imaging cannuals. Imaging cannulas have a transparent glass bottom to allow optical access to the hippocampus. (B). Schematic description of the preparation highlighting the relative position of the imaging cannula, a CA1 PN and the three layers of fibers from dorsal to ventral. (C, D). Schematic description of the imaging setup (C) and of the animal fixation (D) during an imaging session. <a href="https://www.jove.com/files/ftp_upload/59598/59598fig1large.jpg" target="_blank">Please click here to view a larger version of this figure.</a>
<img alt="Figure 2" class="xfigimg" src="/files/ftp_upload/59598/59598fig2.jpg" /> 
Figure 2: Longitudinal imaging of dendritic structure and dendritic spines dynamics. (A). 2P image stack (Maximum Intensity Projection (MIP) of 59 image planes, 2 &#181;m z-spacing) of neurons and dendrites labelled by GFP in a live Thy1-GFP mouse. (B). Higher magnification (MIP of 53 image planes, 1 &#181;m z-spacing) detailing basal dendrites located in SO. (C). Time-lapse image sequence of a dendritic segment imaged over 14 days. Arrowheads indicate dendritic spines tracked over 14 days. (D, E). 2P image stack of neurons and dendrites labelled by GFP in a live Thy1-GFP mouse; (D) ZY projection (31 image planes, 3 &#181;m z-spacing) and (E) XY projections (17 image planes, 3 &#181;m z-spacing). (F). Higher magnification (single image plane) detailing apical dendrites and dendritic spines located in SR. Arrowheads indicate dendritic spines. Excitation: 920 nm; emission peak: 510 nm. Scale bars: A, 50 &#181;m; B, 10 &#181;m; C, 2 &#181;m; D and E, 15 &#181;m; F, 4 &#181;m. <a href="https://www.jove.com/files/ftp_upload/59598/59598fig2large.jpg" target="_blank">Please click here to view a larger version of this figure.</a>
<img alt="Figure 3" class="xfigimg" src="/files/ftp_upload/59598/59598fig3.jpg" /> 
Figure 3: Longitudinal imaging of activity-evoked plasticity. (A). 2P images (single image planes) from a live mouse, showing the same cells on Baseline Day 0 and after EE on Day 1. (B). 2P image stacks (MIPs of 4-6 image planes, 3 &#181;m z-spacing) showing E-SARE activation patterns specific for environment A (Days 1, 19 and 25) and environment B (Days 7 and 13). Green: d2Venus fluorescence. Red: TurboFP635 fluorescence. Excitation: 920 nm; d2Venus emission peak: 530 nm; TurboFP635 emission peak: 635nm. Scale bars: A, 20 &#181;m; B, 10 &#181;m. This figure has been modified from Attardo et al., 201835. <a href="https://www.jove.com/files/ftp_upload/59598/59598fig3large.jpg" target="_blank">Please click here to view a larger version of this figure.</a>
<img alt="Figure 4" class="xfigimg" src="/files/ftp_upload/59598/59598fig4.jpg" /> 
Figure 4: Imaging of neuronal structure in hippocampal DG using three-photon (3P) microscopy. (A-H). 3P images (single image planes) of neurons and dendrites labelled by GFP in a live Thy1-GFP mouse detailing (A-E) PNs in the CA1 and (F-H) granule cells in the DG. Excitation: 1400 nm; emission peak: 510 nm. Scale bar: 40 &#181;m. <a href="https://www.jove.com/files/ftp_upload/59598/59598fig4large.jpg" target="_blank">Please click here to view a larger version of this figure.</a>
Supplementary Movie 1: Imaging field of view in a live Thy1-GFP mouse. 2P image stack (83 image planes, 7 &#181;m z-spacing) of neurons and dendrites labelled by GFP (white) in a live Thy1-GFP mouse extending from the bottom of the cannula to SLM. To account for the decay of fluorescence signal with increasing depth, we used a non-linear gradient of photomultiplier tubes&#8217; gain. <a href="https://www.jove.com/files/ftp_upload/59598/Movie_1_FINAL.avi">Please click here to download this file.</a>
Supplementary Movie 2: Imaging of activity-evoked plasticity. 2P image stack (28 image planes, 3 &#181;m z-spacing) of neurons expressing E-SARE reporter of IEG expression in a live mouse encompassing SP. Green: d2Venus fluorescence. Red: TurboFP635 fluorescence. <a href="https://www.jove.com/files/ftp_upload/59598/Movie_2_FINAL.avi">Please click here to download this file.</a>

Watch this Scientific Journal Video about Longitudinal Two-Photon Imaging of Dorsal Hippocampal CA1 in Live Mice at JoVE.com

Longitudinal Two-Photon Imaging of Dorsal Hippocampal CA1 in Live Mice

Canlı fareler içinde dorsal hipokampal CA1 uzunlamasına Iki foton görüntüleme

This method describes a chronic preparation that allows optical access to the hippocampus of living mice. This preparation can be used to perform longitudinal optical imaging of neuronal structural plasticity and activity-evoked cellular plasticity over a period of several weeks.

Two-photon microscopy is a fundamental tool for neuroscience as it permits investigation of the brain of live animals at spatial scales ranging from ...

longitudinal-two-photon-imaging-of-dorsal-hippocampal-ca1-in-live-mice

Research

JoVE Journal

Behavior

15.5K Görüntüleme.  Max Planck Institute of Psychiatry. Bu prosedür, öğrenme görevlerini yerine getirirken bellek oluşumu ve hatırlama mekanizmalarını incelemek için canlı farelerin sırt hipokampusuna tekrarlanan optik erişim sağlar. Bu teknik, birkaç hafta boyunca uzunlamasına olarak mikrometre düzeyinde canlı farelerin dorsal hipokampus çalışması için ışık mikroskobu kullanımını sağlar. Hafıza kaybı Alzheimer hastalığı gibi bazı beyin hastalıklarının genel bir özelliğidir.Bellek oluşumu ve hatırla...

Video: Longitudinal Two-Photon Imaging of Dorsal Hippocampal CA1 in Live Mice

Shallow Water (Paddling) Variants of Water Maze Tests in Mice

When Richard Morris devised his water maze in 19817, most behavioral work was done in rats. However, the greater understanding of mouse genetics led to the mouse becoming increasingly important. But researchers found that some strains of mutant mice were prone to problems like passively floating or diving when they were tested in the Morris water maze11. This was unsurprising considering their natural habitat; rats swim naturally (classically, the "sewer rat"), whereas mice evolved in the dry areas of central Asia.
To overcome these problems, it was considered whether shallow water would be a sufficient stimulus to provide escape motivation for mice. This would also avoid the problems of drying the small creatures with a towel and then putting them in a heated recovery chamber to avoid hypothermia, which is a much more serious problem than with rats; the large ratio of surface area to volume of a mouse makes it particularly vulnerable to rapid heat loss.
Another consideration was whether a more natural escape strategy could be used, to facilitate learning. Since animals that fall into water and swim away from the safety of the shore are unlikely to pass on their genes, animals have evolved a natural tendency to swim to the edge of a body of water. The Morris water maze, however, requires them to swim to a hidden platform towards the center of the maze - exactly opposite to their evolved behavior. Therefore the paddling maze should incorporate escape to the edge of the apparatus. This feature, coupled with the use of relatively non-aversive shallow water, embodies the "Refinement" aspect of the "3 Rs" of Russell and Burch8.
Various types of maze design were tried; the common feature was that the water was always shallow (2 cm deep) and escape was via a tube piercing the transparent wall of the apparatus. Other tubes ("false exits") were also placed around the walls but these were blocked off. From the inside of the maze all false exits and the single true exit looked the same. Currently a dodecagonal (12-sided) maze is in use in Oxford, with 12 true/false exits set in the corners. In a recent development a transparent paddling Y-maze has been tested successfully.

Shallow Water Paddling Variants of Water Maze Tests in Mice

Mice can swim, but many strains appear to find this activity stressful. To overcome this problem mazes have been devised where escape from shallow water is used to motivate behaviour. These have been demonstrated to support learning at least as good as the traditional and widely used Morris water maze.

Farelerde Su Maze Testleri Sığ Su (kürek çekmeye) Türevleri

When Richard Morris devised his water maze in 19817, most behavioral work was done in rats. However, the greater understanding of mouse genetics led to ...

Davranış

Functional Magnetic Resonance Imaging (fMRI) with Auditory Stimulation in Songbirds

The neurobiology of birdsong, as a model for human speech, is a pronounced area of research in behavioral neuroscience. Whereas electrophysiology and molecular approaches allow the investigation of either different stimuli on few neurons, or one stimulus in large parts of the brain, blood oxygenation level dependent (BOLD) functional Magnetic Resonance Imaging (fMRI) allows combining both advantages, i.e. compare the neural activation induced by different stimuli in the entire brain at once. fMRI in songbirds is challenging because of the small size of their brains and because their bones and especially their skull comprise numerous air cavities, inducing important susceptibility artifacts. Gradient-echo (GE) BOLD fMRI has been successfully applied to songbirds 1-5 (for a review, see 6). These studies focused on the primary and secondary auditory brain areas, which are regions free of susceptibility artifacts. However, because processes of interest may occur beyond these regions, whole brain BOLD fMRI is required using an MRI sequence less susceptible to these artifacts. This can be achieved by using spin-echo (SE) BOLD fMRI 7,8 . In this article, we describe how to use this technique in zebra finches (Taeniopygia guttata), which are small songbirds with a bodyweight of 15-25 g extensively studied in behavioral neurosciences of birdsong. The main topic of fMRI studies on songbirds is song perception and song learning. The auditory nature of the stimuli combined with the weak BOLD sensitivity of SE (compared to GE) based fMRI sequences makes the implementation of this technique very challenging.

Functional Magnetic Resonance Imaging fMRI with Auditory Stimulation in Songbirds

This article shows an optimized procedure for imaging of the neural substrates of auditory stimulation in the songbird brain using functional Magnetic Resonance Imaging (fMRI). It describes the preparation of the sound stimuli, the positioning of the subject and the acquisition and subsequent analysis of the fMRI data.

Songbirds İşitsel Uyarım ile Fonksiyonel Manyetik Rezonans Görüntüleme (fMRI)

The neurobiology of birdsong, as a model for human speech, is a pronounced area of research in behavioral neuroscience. Whereas electrophysiology and ...

Stereotactic Injection of MicroRNA-expressing Lentiviruses to the Mouse Hippocampus CA1 Region and Assessment of the Behavioral Outcome

MicroRNAs (miRNAs) are small regulatory single-stranded RNA molecules around 22 nucleotides long that may each target numerous mRNA transcripts and dim an entire gene expression pathway by inducing destruction and/or inhibiting translation of these targets. Several miRNAs play key roles in maintaining neuronal structure and function and in higher-level brain functions, and methods are sought for manipulating their levels for exploring these functions. Here, we present a direct in vivo method for examining the cognitive consequences of enforced miRNAs excess in mice by stereotactic injection of miRNA-encoding virus particles. Specifically, the current protocol involves injection into the hippocampal CA1 region, which contributes to mammalian memory consolidation, learning, and stress responses, and offers a convenient injection site. The coordinates are measured according to the mouse bregma and virus perfusion is digitally controlled and kept very slow. After injection, the surgery wound is sealed and the animals recover. Lentiviruses encoding silencers of the corresponding mRNA targets serve to implicate the specific miRNA/target interaction responsible for the observed effect, with na&iuml;ve mice, mice injected with saline and mice injected with "empty" lentivirus vectors as controls. One month post-injection, the animals are examined in the Morris Water Maze (MWM) for assessing their navigation learning and memory abilities. The MWM is a round tank filled with colored water with a small platform submerged 1 cm below the water surface. Steady visual cues around the tank allow for spatial navigation (sound and the earth's magnetic field may also assist the animals in navigating). Video camera monitoring enables measuring the route of swim and the time to find and amount the platform. The mouse is first taught that mounting the hidden platform offers an escape from the enforced swimming; it is then tested for using this escape and finally, the platform is removed and probe tests examine if the mouse remembers its previous location. Repeated tests over several consecutive days highlight improved performance of tested mice at shorter latencies to find and mount the platform, and as more direct routes to reach the platform or its location. Failure to show such improvement represents impaired learning and memory and/or anxiety, which may then be tested specifically (e.g. in the elevated plus maze). This approach enables validation of specific miRNAs and target transcripts in the studied cognitive and/or stress-related processes.

MicroRNAs have significant roles in brain structure and function. Here we describe a method to enforce hippocampal miRNA over-expression using stereotactic injection of an engineered miRNA-expressing lentivirus. This approach can serve as a relatively rapid way to assess the in vivo effects of over-expressed miRNAs in specific brain regions.

Bir Stereotaktik Enjeksiyon MicroRNA-ifade Fare Hippocampus CA1 Bölgesi Lentiviruses ve Davranış Sonuç Değerlendirilmesi

MicroRNAs (miRNAs) are small regulatory single-stranded RNA molecules around 22 nucleotides long that may each target numerous mRNA transcripts and dim an ...

Two-photon Calcium Imaging in Mice Navigating a Virtual Reality Environment

In recent years, two-photon imaging has become an invaluable tool in neuroscience, as it allows for chronic measurement of the activity of genetically identified cells during behavior1-6. Here we describe methods to perform two-photon imaging in mouse cortex while the animal navigates a virtual reality environment. We focus on the aspects of the experimental procedures that are key to imaging in a behaving animal in a brightly lit virtual environment. The key problems that arise in this experimental setup that we here address are: minimizing brain motion related artifacts, minimizing light leak from the virtual reality projection system, and minimizing laser induced tissue damage. We also provide sample software to control the virtual reality environment and to do pupil tracking. With these procedures and resources it should be possible to convert a conventional two-photon microscope for use in behaving mice.

Here we describe the experimental procedures involved in two-photon imaging of mouse cortex during behavior in a virtual reality environment.

Sanal Gerçeklik Çevre gezinme Farelerde iki foton Kalsiyum Görüntüleme

In recent years, two-photon imaging has become an invaluable tool in neuroscience, as it allows for chronic measurement of the activity of genetically ...

Trace Fear Conditioning in Mice

In this experiment we present a technique to measure learning and memory. In the trace fear conditioning protocol presented here there are five pairings between a neutral stimulus and an unconditioned stimulus. There is a 20 sec trace period that separates each conditioning trial. On the following day freezing is measured during presentation of the conditioned stimulus (CS) and trace period. On the third day there is an 8 min test to measure contextual memory. The representative results are from mice that were presented with the aversive unconditioned stimulus (shock) compared to mice that received the tone presentations without the unconditioned stimulus. Trace fear conditioning has been successfully used to detect subtle learning and memory deficits and enhancements in mice that are not found with other fear conditioning methods. This type of fear conditioning is believed to be dependent upon connections between the medial prefrontal cortex and the hippocampus. One current controversy is whether this method is believed to be amygdala-independent. Therefore, other fear conditioning testing is needed to examine amygdala-dependent learning and memory effects, such as through the delay fear conditioning.

In the following experiment we describe a protocol for trace fear conditioning in mice. This type of associative memory includes a trace period that separates the neutral stimulus and the unconditioned stimulus.

Farelerde Korku Yastıkları Trace

In this experiment we present a technique to measure learning and memory. In the trace fear conditioning protocol presented here there are five pairings ...

Measurement of Fronto-limbic Activity Using an Emotional Oddball Task in Children with Familial High Risk for Schizophrenia

Adolescence is a critical developmental period where the early symptoms of schizophrenia frequently emerge. First-degree relatives of people with schizophrenia who are at familial high risk (FHR) may show similar cognitive and emotional changes. However, the neurological changes underlying the emergence of these symptoms remain unclear. This study sought to identify differences in frontal, striatal, and limbic regions in children and adolescents with FHR using functional magnetic resonance imaging. Groups of 21 children and adolescents at FHR and 21 healthy controls completed an emotional oddball task that relied on selective attention and the suppression of task-irrelevant emotional information. The standard oddball task was modified to include aversive and neutral distractors in order to examine potential group differences in both emotional and executive processing. This task was designed specifically to allow for children and adolescents to complete by keeping the difficulty and emotional image content age-appropriate. Furthermore, we demonstrate a technique for suitable fMRI registration for children and adolescent participants. This paradigm may also be applied in future studies to measure changes in neural activity in other populations with hypothesized developmental changes in executive and emotional processing.

This paper describes how to use the emotional oddball task and fMRI to measure brain activation in children and adolescents at familial high risk for schizophrenia (FHR).&#160;FMRI was used to measure differences in fronto-striato-limbic regions during an emotional oddball task. Children with FHR exhibited abnormal functional activation during adolescence.

Şizofreni ailesel Riskli Çocuklarda Duygusal Oddball Görev Kullanımı Fronto-limbik Faaliyet Ölçümü

Adolescence is a critical developmental period where the early symptoms of schizophrenia frequently emerge. First-degree relatives of people with ...

The Modified Hole Board - Measuring Behavior, Cognition and Social Interaction in Mice and Rats

This protocol describes the modified hole board (mHB), which combines features from a traditional hole board and open field and is designed to measure multiple dimensions of unconditioned behavior in small laboratory mammals (e.g., mice, rats, tree shrews and small primates). This paradigm is a valuable alternative for the use of a behavioral test battery, since a broad behavioral spectrum of an animal&#8217;s behavioral profile can be investigated in one single test.
The apparatus consists of a box, representing the &#8216;protected&#8217; area, separated from a group compartment. A board, on which small cylinders are staggered in three lines, is placed in the center of the box, representing the &#8216;unprotected&#8217; area of the set-up. The cognitive abilities of the animals can be measured by baiting some cylinders on the board and measuring the working and reference memory. Other unconditioned behavior, such as activity-related-, anxiety-related- and social behavior, can be observed using this paradigm. Behavioral flexibility and the ability to habituate to a novel environment can additionally be observed by subjecting the animals to multiple trials in the mHB, revealing insight into the animals&#8217; adaptive capacities.
Due to testing order effects in a behavioral test battery, na&#239;ve animals should be used for each individual experiment. By testing multiple behavioral dimensions in a single paradigm and thereby circumventing this issue, the number of experimental animals used is reduced. Furthermore, by avoiding social isolation during testing and without the need to food deprive the animals, the mHB represents a behavioral test system, inducing if any, very low amount of stress.

This protocol describes the modified hole board, which is a behavioral test set-up that comprises the characteristics of an open field and a traditional hole board. This set-up enables the differential analysis of unconditioned behavior of small laboratory mammals as well as the analysis of cognitive abilities.

Modifiye Delik Kurulu - Fareler ve Sıçanlarda Davranışı, Biliş ve Sosyal Etkileşim Ölçme

This protocol describes the modified hole board (mHB), which combines features from a traditional hole board and open field and is designed to measure ...

Using Fiberless, Wearable fNIRS to Monitor Brain Activity in Real-world Cognitive Tasks

Functional Near Infrared Spectroscopy (fNIRS) is a neuroimaging technique that uses near-infrared light to monitor brain activity. Based on neurovascular coupling, fNIRS is able to measure the haemoglobin concentration changes secondary to neuronal activity. Compared to other neuroimaging techniques, fNIRS represents a good compromise in terms of spatial and temporal resolution. Moreover, it is portable, lightweight, less sensitive to motion artifacts and does not impose significant physical restraints. It is therefore appropriate to monitor a wide range of cognitive tasks (e.g., auditory, gait analysis, social interaction) and different age populations (e.g., new-borns, adults, elderly people). The recent development of fiberless fNIRS devices has opened the way to new applications in neuroscience research. This represents a unique opportunity to study functional activity during real-world tests, which can be more sensitive and accurate in assessing cognitive function and dysfunction than lab-based tests. This study explored the use of fiberless fNIRS to monitor brain activity during a real-world prospective memory task. This protocol is performed outside the lab and brain haemoglobin concentration changes are continuously measured over the prefrontal cortex while the subject walks around in order to accomplish several different tasks.

Monitoring brain activity outside the lab without physical constraints presents methodological challenges. A fiberless, wearable functional Near Infrared Spectroscopy (fNIRS) system was used to measure brain activity during an ecological prospective memory task. It was demonstrated that this system could be used to monitor brain activity during non-lab based experiments.

Gerçek dünya Bilişsel Görevler Beyin Aktivite Monitör lifsiz, Giyilebilir fNIRS kullanma

Functional Near Infrared Spectroscopy (fNIRS) is a neuroimaging technique that uses near-infrared light to monitor brain activity. Based on neurovascular ...

Multi-layer Cortical Ca2+ Imaging in Freely Moving Mice with Prism Probes and Miniaturized Fluorescence Microscopy

In vivo circuit and cellular level functional imaging is a critical tool for understanding the brain in action. High resolution imaging of mouse cortical neurons with two-photon microscopy has provided unique insights into cortical structure, function and plasticity. However, these studies are limited to head fixed animals, greatly reducing the behavioral complexity available for study. In this paper, we describe a procedure for performing chronic fluorescence microscopy with cellular-resolution across multiple cortical layers in freely behaving mice. We used an integrated miniaturized fluorescence microscope paired with an implanted prism probe to simultaneously visualize and record the calcium dynamics of hundreds of neurons across multiple layers of the somatosensory cortex as the mouse engaged in a novel object exploration task, over several days. This technique can be adapted to other brain regions in different animal species for other behavioral paradigms.

Multi-layer Cortical Ca2+ Imaging in Freely Moving Mice with Prism Probes and Miniaturized Fluorescence Microscopy

Here, we present a procedure for performing large-scale Ca2+ imaging with cellular-resolution across multiple cortical layers in freely moving mice. Hundreds of active cells can be observed simultaneously using a miniature, head-mounted microscope coupled with an implanted prism probe.

Çok Katlı Kortikal Ca<sup&gt; 2+</sup&gt; Prizmatik Problar ve Minyatür Floresan Mikroskopi ile Serbestçe Hareketli Fare Görüntüleme

In vivo circuit and cellular level functional imaging is a critical tool for understanding the brain in action. High resolution imaging of mouse cortical ...

Assessing Activity-based Anorexia in Mice

Rodents develop activity-based anorexia (ABA) when exposed to a restricted feeding schedule and allowed free access to a running wheel. These conditions lead to a life-threatening reduction in body weight. However, rodents exposed to only one of these conditions ultimately adapt to re-establish normal body weight. Although increased running coupled with reduction in voluntary food intake appear paradoxical under ABA conditions, ABA behavior is observed across numerous mammalian species. 
The ABA paradigm provides an animal model for anorexia nervosa (AN), an eating disorder with severe dysregulation of appetite-behavior. Subjects are singly housed with free access to a running wheel. Each day, the subject is offered food for a limited amount of time. During the course of the experiment, a subject's body weight decreases from high activity and low caloric intake. The duration of the study varies based on how long food is offered daily, the type of food offered, the strain of mouse, if drugs are being tested, and environmental factors.
A lack of effective pharmacological treatments for AN patients, their low quality of life, high cost of treatment, and their high mortality rate indicate the urgency to further research AN. We provide a basic outline for performing ABA experiments with mice, offering a method to investigate AN-like behavior in order to develop novel therapies. This protocol is optimized for use in Balb/cJ mice, but can easily be manipulated for other strains, providing great flexibility in working with different questions, especially related to genetic factors of ABA.

Mice individually housed with a running wheel while given limited access to food develop reductions in food consumption and increase activity on the running wheel. This experimental phenomenon is called activity-based anorexia. This paradigm provides an experimental tool for studying the neurobiology and behaviors underlying aspects of anorexia nervosa.

Etkinlik tabanlı anoreksiya farelerde değerlendirilmesi

Rodents develop activity-based anorexia (ABA) when exposed to a restricted feeding schedule and allowed free access to a running wheel. These conditions ...