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Hippocampal function is not required for the precision of remote place memory

Molecular Brain volume 5, Article number: 5 (2012) Cite this article

Abstract

Background

During permanent memory formation, recall of acquired place memories initially depends on the hippocampus and eventually become hippocampus-independent with time. It has been suggested that the quality of original place memories also transforms from a precise form to a less precise form with similar time course. The question arises of whether the quality of original place memories is determined by brain regions on which the memory depends.

Results

To directly test this idea, we introduced a new procedure: a non-associative place recognition memory test in mice. Combined with genetic and pharmacological approaches, our analyses revealed that place memory is precisely maintained for 28 days, although the recall of place memory shifts from hippocampus-dependent to hippocampus-independent with time. Moreover, the inactivation of the hippocampal function does not inhibit the precision of remote place memory.

Conclusion

These results indicate that the quality of place memories is not determined by brain regions on which the memory depends.

Introduction

The hippocampus is a key brain structure for learning and memory [1–3]. Recall of some associative and spatial memories initially depends on the hippocampus, but that hippocampal dependency progressively decays over time, a process that is associated with a gradual increase of neocortex-dependency [4–9]. It has been suggested that the quality of original memories also transforms from a precise (i.e., detailed) form to a less precise (i.e., more schematic or generic) form with similar time course [10–12]. The question arises of whether changes in the quality of the original memories depend on the shift in brain regions on which the recall of these memories relies, i.e., whether the hippocampus is always required for the precision of memories. This is an important question for understanding physiological significances of the hippocampal-cortical complementary memory systems.

There are several studies that address this issue in rodents. Using a contextual fear conditioning paradigm, which is an associative learning between a place and aversive experience, some studies demonstrated that the hippocampus is always necessary for the precision of place memories [13, 14], supporting the memory transformation view [11] in which the quality of place memory correlates with the brain region on which that memory depends. By contrast, another study demonstrated that the hippocampus is not required for memory precision after the passage of time [15], supporting the memory reorganization view [9] in which the quality of place memory does not correlate with the brain region. Importantly, this discrepancy can be attributed to differences in experimental protocols used for association with fear [15]. Because association with fear modifies (i.e., strengthen or generalize) the precision [16, 17], we cannot rule out the possibility that fear association may mask the actual precision of place memory. Moreover, contextual fear conditioning indirectly evaluates the place memory by measuring fear responses. Analyses based on association procedures may not be suitable for evaluating the precision. A direct way to address this issue is to measure the place memory per se without association protocols. In this study, we introduced a new procedure: a one-trial and non-associative place recognition test in mice. The clear advantage is the absence of any explicit reinforcement. In this procedure, we simply placed mice in a previously experienced vs. novel place. In the previously experienced place, mice exhibited habituation (reduced motility). In the novel context, mice did not show this reduction in motility. Thus, we evaluated the adaptation level as an index of the successful retrieval of place memory. Mice quickly acquired place memory during a free exploration and clearly discriminate experienced place from novel place. Especially mice maintained these memories for one month, which is different from the case in rats [18]. This procedure allows us to directly evaluate the precision of remote place memory. Using this procedure combined with genetic and pharmacological approaches, we examined the relationship between the precision of place memory and the brain region on which that memory depends.

Materials & methods

Animals

All animal procedures were conducted in compliance with the guidelines of the National Institutes of Health and were approved by the Animal Care and Use Committee of the University of Toyama and the Mitsubishi Kagaku Institute of Life Sciences. For WT experiments, male C57BL/6JSLC mice at 8 weeks of age were purchased from Sankyo Laboratory (Japan). For experiments using inducible cAMP response element binding protein (CREB) repressor transgenic mice [19, 20] and α-Calcium-calmodulin kinase II heterozygous null mutant mice [21–23], the progeny for each line was produced using in vitro fertilization and embryo transfer techniques to produce a number of animals sufficient for behavioral testing. Age- and gender-matched littermates were used for the tests. All behavioral experiments were conducted and analyzed by scientists blind to the genotypes of the animals. Food and water were provided ad libitum.

Cannulation and drug infusion

We used a surgical procedure described previously [24, 25]. Briefly, mice were implanted bilaterally with stainless steel guide cannulae (Eicom) using the following stereotactic coordinates: AP = -2.0 mm, ML = ± 1.5 mm, V = -2.1 mm from the bregma. Mice were allowed to recover for at least 14 days in individual home cages. To transiently inactivate hippocampus, a fluorescently-labeled γ-aminobutyric acid subtype A receptor agonist (FCM, fluorophore-conjugated muscimol; Molecular Probe) was used. Mice were briefly anesthetized with isoflurane to facilitate the insertion of the injection cannula. FCM (0.8 mM, 0.5 ul) or PBS alone was infused into the dorsal hippocampus at a rate of 0.20 μl/min 60 min before the retrieval test. The fluorescent signals of FCM were distributed in the dorsal hippocampus bilaterally. To inhibit protein synthesis in the hippocampus, anisomycin (ANI, 100 μg/μl, 0.75 μl; Sigma) was infused into the dorsal hippocampus bilaterally at a rate of 0.25 μl/min 10 minutes after the learning. For the i.p. injection of ANI, ANI (150 mg/kg, i.p.) was dissolved in PBS (pH adjusted to 7.0-7.4) and administered to mice 10 minutes after the learning. At this dose, ANI inhibits 90% of protein synthesis in the brain during the first 2 hours [26]. For the i.p. injection of (R)-CPP (10 mg/kg, i.p.; Tocris), an antagonist of N-methyl-D-aspartate receptors, (R)-CPP was dissolved in PBS and administered to mice 4.5 hours before the learning. To examine the effects of disrupting CREB function on place memory formation, we used the transgenic mice that express an inducible CREB repressor in the forebrain, where a dominant-negative CREB protein is fused with the ligand binding domain of a mutant estrogen receptor [19]. Tamoxifen (4-hydroxytamoxifen; 16 mg/kg, i.p. TAM; Sigma), which was dissolved in 10 ml of peanut oil (Sigma), or peanut oil only (OIL) was administered to WT or transgenic mice 6 hours before the learning session.

Place memory test

Mice were housed individually in plastic cages with laboratory bedding at least 2 weeks before behavioral analyses and maintained on a 12:12 h light:dark cycle. Learning and testing sessions were conducted during the light cycle in a dedicated soundproof behavioral room (Room A: ASA4030, DR40, YAMAHA, JAPAN, (width × depth × height: 1640 × 1640 × 2160 mm, respectively) or other behavioral room (Room B: width × depth × height: 3200 × 4380 × 2240 mm, respectively). The square-type (S) chamber had a transparent acrylic-board front wall and gray side and back walls (width × depth × height: 175 × 165 × 300 mm, respectively), and the chamber floors consisted of 26 stainless steel rods with a diameter of 2 mm that were placed 5 mm apart. The circle-type (C) chamber is cylindrical (diameter × height: 170 × 270 mm, respectively) and has a white acrylic-board wall and floor (Figure 1B). During the learning session, mice were placed in the chamber (S or C chamber). After 6 minutes, mice were then returned to their home cages. During the testing session, mice were placed back into experienced chamber or the novel chamber for 3 minutes. At the end of each session, mice were returned to their home cages and the chambers were cleaned with water and 80% ethanol. All experiments were conducted using a video tracking system (Muromachi Kikai; Japan) to measure the motility of the animals. The motility was calculated as the cumulative area of movement (pixel size) per 0.1 sec in the learning and testing sessions.

Figure 1
figure 1

Mice discriminate places in non-associative place recognition test. A, Experimental design. B, Photographs of a square-type chamber and a circular-type chamber. Scale bars, 10 cm. C, Recent place memory test. Kinetics of motility in the learning and testing sessions. Blue line, S-S; red line, S-C; n = 6-7/group. D, Motility in the first 3 minutes during the learning or testing session in chamber S (white bars) or chamber C (black bars). n = 6-7/group. ***P < 0.001, **P < 0.01. Error bars indicate SEM.

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Contextual fear conditioning

Contextual fear conditioning was carried out as described previously [24, 27, 28]. Briefly, during the training session, mice were placed in the conditioning chamber (S) in Room A. After 3 minutes, animals were subjected to three unsignaled footshocks (2 sec duration, 0.5 mA, a min apart). After the last shock, mice remained in the chamber for 1 minute and were then returned to their home cages. During the testing session, mice were placed back into the conditioning chamber (S) or the novel chamber (C) for 3 minutes in Room A at 1 day or 28 days after training. At the end of each session, mice were returned to their home cages and the chambers were cleaned with water and 80% ethanol. All experiments were conducted using a video tracking system (Muromachi Kikai; Japan) to measure the freezing behavior of the animals. Freezing was defined as a complete absence of movement, except for respiration. Scoring of the duration of the freezing responses was started after 1 sec of sustained freezing behavior.

Statistical analyses

All data are presented as mean ± SEM. The number of animals used is indicated by "n". Comparisons between two-group data were analyzed by unpaired Student's t-tests or paired t-tests. Multiple group comparisons were assessed using a one-way, two-way, or repeated measures analysis of variance (ANOVA), followed by the post-hoc Scheffe's test when significant main effects or interactions were detected. The null hypothesis was rejected at the P < 0.05 level.

Results

Mice were exposed to a novel square-type (S) chamber to learn this place (Figure 1A, B). One day later, mice were again exposed to the same chamber or a novel circle-type (C) chamber to test memory retrieval (Figure 1A, C). We monitored the motility of mice in the chambers and evaluated the adaptation level for the experienced or novel chamber as an index of the successful retrieval of place memory (Figure 1C, D). Mice showed a reduction in their motility when exposed to the same S chamber (paired t-test; t6 = 9.96, P < 0.001) (Figure 1D). By contrast, a six-minute exposure to the S chamber did not induce adaptation in the novel C chamber (paired t-test; t6 = -0.07, P > 0.9) (Figure 1C, D). We obtained a similar result when we changed the sequence (C-C paired t-test: t5 = 8.39, P < 0.001; C-S paired t-test: t6 = 1.16, P > 0.2) (Figure 1D). These results indicate that mice quickly learn the place and completely discriminate the experienced place from the novel place one day after learning. Thus, the adaptation can be used to index place memory.

To validate the potency of this procedure as place memory test, we have characterized the molecular mechanisms of place memory formation (Figure 2). We found that the injection of NMDA receptor antagonist disrupted the adaptation 1 day after learning (Figure 2A), and that the tamoxifen-injected CREB transgenic mice showed less adaptation for chamber S compared with the other groups (Figure 2B), and that an injection of anisomycin into the dorsal hippocampus disrupted the adaptation 1 day after learning (Figure 2E) but not short-term memory (Figure 2C, D). Thus, similar to other forms of hippocampus-dependent memory [3, 29], the place memory formation requires the NMDA receptor function, the CREB-mediated transcription (Figure 2B), and the protein synthesis in the hippocampus.

Figure 2
figure 2

Place memory formation requires NMDA receptor function, CREB-mediated transcription, and protein synthesis in the hippocampus. A-E, Experimental design used with data presented below. A, Effect of an antagonist of the NMDA receptor on place memory formation. Motility in the first 3 minutes during the learning or testing session in chamber S. SAL (saline), CPP, or CPP treatment-only (homecage) groups. There was a significant interaction between adaptation and drug treatment (repeated ANOVA: F(1, 47) = 13.42, P < 0.01). n = 10-12/group. B, Effect of inducible repression of CREB function on place memory formation. Motility in the first 3 minutes during the learning or testing session in chamber S. There was a significant interaction between adaptation and genotype (repeated ANOVA: F(1, 31) = 7.32, P < 0.02). n = 6-9/group. C, Effect of i.p. injection of ANI on long-term place memory. Motility in the first 3 minutes during the learning or testing session in chamber S. SAL, ANI, or ANI treatment-only (homecage) groups. Injection of ANI disrupted long-term place memory. There was a significant interaction between adaptation and drug (repeated ANOVA: F(1, 47) = 15.89, P < 0.001). n = 10-12/group. D, Effect of i.p. injection of ANI on short-term place memory. Injection of ANI did not affect short-term place memory. n = 10/group. E, Effect of infusion of ANI into dorsal hippocampus on consolidation of place memory. There was a significant interaction between adaptation and drug (repeated ANOVA: F(1, 21) = 12.14, P < 0.001). n = 5-6/group. ***P < 0.001. **P < 0.01. *P < 0.05. Error bars indicate SEM.

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Next, we examined the maintenance of place memory 28 days after learning (Figure 3A). In the retrieval test, mice showed adaptation for the experienced S chamber (paired t-test: t5 = 6.48, P < 0.002), but not for the novel C chamber (paired t-test: t5 = 0.35, P > 0.7) (Figure 3A), indicating that mice can discriminate the experienced place from the novel place 28 days after learning. We further examined the precision of their remote place memory in a variable-rooms/constant-chamber condition, in which mice were placed for 6 minutes in the S chamber in room A and 28 days later these mice were placed in the same S chamber in a different room B (Figure 3A). In novel room B, mice did not show adaptation, even for the previously experienced S chamber (A-B, paired t-test: t10 = -1.69, P > 0.1) (Figure 3A), indicating that mice can detect changes outside of the chamber. This seems to be a similar feature of hippocampal representations, global remapping, in which both the firing location and firing rates of hippocampal pyramidal cells change in variable-room/constant-chamber conditions [30, 31]. These results indicate that the precision of place memory does not decline with time in mice, even with one-trial learning. In marked contrast, mice seemed not to discriminate between the S chamber and the C chamber in a remote memory test for contextual fear conditioning (Figure 3B). Mice showed high freezing behavior in both chambers in the 28-day memory retrieval test (S vs C, t37 = -0.20, P > 0.8), although mice showed less freezing in the novel C chamber than in the conditioning S chamber in a one-day memory retrieval test (S vs C, t17 = 3.18, P < 0.01) (Figure 1E), as previously reported [13, 15, 24, 32–34]. These results indicate that the fear association can mask the precision of place memory, whose mechanisms may be related to feed-forward inhibition growth in the hippocampus [34].

Figure 3
figure 3

The precision of non-associative place memory does not decline with time. A, B, Experimental design used with data presented below. A, Remote place memory in non-associative place memory test. Motility in the first 3 minutes during the learning or testing session in chamber S/Room A (white bar), or chamber C/Room A (black bar), or chamber S/Room B (gray bar). There was a significant interaction between adaptation and chamber (chamber S/Room A vs chamber C/Room A; repeated ANOVA: F(1, 23) = 13.54, P < 0.01) (chamber S/Room A vs chamber S/Room B; repeated ANOVA: F(1, 33) = 31.86, P < 0.001). n = 6-11/group. B, Recent (1 day: n = 9-10/group) or remote (28 days: n = 19-20/group) contextual fear conditioning memory tests. Training was carried out in the S chamber. Freezing behavior averaged over the 3-minute test sessions in chamber S/Room A (conditioned, white bars) or chamber C/Room A (novel, black bars). There was a significant interaction between day and chamber (two-way ANOVA: F(1, 58) = 10.08, P < 0.01). ***P < 0.001, **P < 0.01. Error bars indicate SEM.

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Alpha-calcium-calmodulin kinase II (α-CaMKII) heterozygous null mutant (HKO) mice [21] have severe deficits in cortical long-term potentiation (LTP), whereas hippocampal CA1 LTP is normal [35]. The HKO mice showed high motility compared with age-matched litter mate wild-type mice (motility/3 min in Chamber S; WT (n = 10), 192876 ± 11743 pixel; HKO (n = 10), 274844 ± 15573 pixel; t18 = -4.2, P < 0.001), as previously reported [22]. Interestingly, HKO mice showed a complete deficit in place memory 28 days later (paired t-test: t12 = -0.36, P > 0.7), whereas one-day memory was normal (paired t-test; t13 = 9.09, P < 0.001) (Figure 4A). This suggests that cortical plasticity contributes to remote place memory formation. Here, we hypothesized that place memory temporally depends on the hippocampus. To test this, we assessed the contribution of the hippocampus to the retrieval of recent and remote place memories through the transient and pharmacological inactivation of the dorsal hippocampus (Figure 4B-D) [24]. The intrahippocampal infusion of fluorescently-labeled muscimol (FCM) [36] significantly inhibited the retrieval of 1-day memory (Figure 4B). The infusion of FCM also disrupted memory formation (Figure 4C). Treatment with FCM infusion alone did not affect natural motility (Figure 4B, C). Thus, hippocampal function is essential for the formation and retrieval of recent place memory. Next we examined the remote memory test. In the retrieval test for 28-day memory, both FCM- and phosphate buffered saline (PBS)-infused mice clearly showed adaptation to remotely experienced S chamber (PBS paired t-test: t9 = 6.30, P < 0.001; FCM paired t-test: t10 = 16.9, P < 0.001) (Figure 4D, left panel). There was no interaction between adaptation and drug treatment (repeated ANOVA: F(1, 41) = 0.35, P > 0.5). Subsequently, the same animals were subjected to recent memory retrieval test in which hippocampus was inactivated 60 min before the test by additional FCM infusion. The infusion of FCM significantly inhibited adaptation for the recently experienced C chamber (Figure 4D, right panel). There was a significant interaction between adaptation and drug treatment (repeated ANOVA: F(1, 41) = 27.1, P < 0.001), indicating that the FCM infusion effectively inactivated the hippocampal function in these animals. Therefore, the retrieval of remote place memory is completely hippocampal neuronal activity-independent.

Figure 4
figure 4

The retrieval and precision of remote, but not recent, place memory does not require hippocampal function. A-E, Experimental design used with data presented below. A, Recent and remote place memory in CaMK II heterozygous null mutant (HKO) mice. Motility in the first 3 minutes during the learning and testing session. There was a significant interaction between adaptation and day (repeated ANOVA: F(1, 53) = 36.55, P < 0.001). n = 13-14/group. B, C, Effect of the fluorescently-labeled muscimol (FCM) injection into the hippocampus on the formation (C) and the retrieval (B) of recent place memory. Motility in the first 3 minutes during the learning or testing session. There was a significant interaction between adaptation and drug (Figure 4B, repeated ANOVA: F(1, 29) = 23.61, P < 0.001) (Figure 4C, repeated ANOVA: F(1, 33) = 21.29, P < 0.001). D, Effect of FCM infusion into the hippocampus on the retrieval of remote and recent place memory. Chamber S was used for the remote memory retrieval test. Chamber C was used for the recent memory retrieval test. n = 10-11/group. E, Effect of the FCM infusion into the hippocampus on the retrieval of remote place memory in different chambers and rooms. Motility in the first 3 minutes during the learning or testing session. There was a significant interaction between adaptation and chamber (chamber S/Room A vs chamber C/Room A; repeated ANOVA: F(1, 39) = 35.71, P < 0.001) (chamber S/Room A vs chamber S/Room B; repeated ANOVA: F(1, 43) = 34.99, P < 0.001). n = 10-12/group. ***P < 0.001. Error bars indicate SEM.

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Finally, we examined whether hippocampal function is required for the precision of remote place memory retrieval. In the retrieval test for 28-day memory, FCM-infused mice were placed in the experienced S chamber or novel C chamber (Figure 4E). FCM-infused mice showed adaptation for the experienced S chamber (paired t-test: t9 = 12.06, P < 0.001), whereas FCM-infused mice did not show adaptation for the novel C chamber (paired t-test: t9 = -0.68, P > 0.5) (Figure 4E). We further examined the variable-rooms/constant-chamber condition 28 days after learning (Figure 4E). Similar to naive mice (Figure 3A), FCM-infused mice did not show adaptation for the experienced S chamber in the novel room B (paired t-test: t11 = -0.84, P > 0.4) (Figure 4E). These results indicate that the pharmacological inactivation of hippocampal function does not inhibit the precision of remote place memory.

Discussion

In this study, we carried out the contextual fear conditioning test and the non-associative place recognition test under the same experimental condition (same chambers and same exposure time to chamber) (Figure 3). These results clearly indicate that the association with fear masks the actual precision of place memory. Moreover, in contextual fear conditioning mice showed the freezing responses even for unconditioned place in recent memory test (Figure 3B) [13, 15, 24, 32–34], whereas in our non-associative place recognition test mice did not show any adaptation behavior even for similar place in remote memory test (Figure 3A). Therefore, the conclusions of previous studies using contextual fear conditioning [13–15] need to be validated by non-associative protocol. Thus, we examined the contribution of hippocampal function on the precision of remote place memory by non-associative place recognition test.

Using this procedure, we found that the place memory is precisely maintained for 28 days, which may require α-CaMKII-dependent plasticity in the cortex, and that the retrieval of remote place memory (not recent memory) does not require hippocampal function. These results indicate that the quality of a place memory does not correlate with the brain region on which that memory depends. Moreover, we found that the inactivation of hippocampal function does not inhibit the precision of remote place memory. These results indicate that the hippocampal function is not required for the precision of remote place memory. This is consistent with a human case study in which a patient with bilateral extensive hippocampal damage showed intact memories for places learned long ago, but not intact recent place memory [37]. Eight patients with bilateral hippocampal damage were able to recall their remote autobiographical memories [38]. Thus, the quality of original place memories is not determined by brain regions on which the memory depends.

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Acknowledgements

We thank S. Kamijo, M. Matsuo and H. Hidaka for the care of the animals. We also thank B. Wiltgen and N. Ohkawa for reading the manuscript and for discussions, and all members of the Inokuchi laboratory for daily discussions. This work was supported by the Core Research for Evolutional Science and Technology (CREST) program of the Japan Science and Technology Agency (JST) to K.I., a Grant-in-Aid for Scientific Research (S) to K.I., the Mitsubishi Foundation to K.I., the Uehara Memorial Foundation to K.I., a Grant-in-Aid for Young Scientists (B) to T.K., and the Sasagawa Scientific Research Grant to T.K.

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  1. Takashi Kitamura

    Present address: RIKEN-MIT Center for Neural Circuit Genetics and the Picower Institute for Learning and Memory, Massachusetts Institute of Technology, Cambridge, 02139, USA

Authors and Affiliations

  1. Department of Biochemistry, Faculty of Medicine, Graduate School of Medicine & Pharmaceutical Sciences, University of Toyama, Toyama, 930-0194, Japan

    Takashi Kitamura, Reiko Okubo-Suzuki & Kaoru Inokuchi

  2. Japan Science and Technology Agency, CREST, Kawaguchi, 332-0012, Japan

    Takashi Kitamura, Reiko Okubo-Suzuki, Noriko Takashima, Akiko Murayama, Satoshi Kida & Kaoru Inokuchi

  3. Mitsubishi Kagaku Institute of Life Sciences, MITILS, Machida, Tokyo, 194-8511, Japan

    Takashi Kitamura, Reiko Okubo-Suzuki, Noriko Takashima, Akiko Murayama, Toshiaki Hino & Kaoru Inokuchi

  4. Division of Animal Experimental Laboratory, Life Science Research Center, University of Toyama, Toyama, 930-0194, Japan

    Hirofumi Nishizono

  5. Department of Bioscience, Faculty of Applied Bioscience, Tokyo University of Agriculture, Tokyo, 156-8502, Japan

    Satoshi Kida

Authors
  1. Takashi Kitamura
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  2. Reiko Okubo-Suzuki
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  8. Kaoru Inokuchi
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Correspondence to Kaoru Inokuchi.

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The authors declare that they have no competing interests.

Authors' contributions

T.K. and K.I. designed research; T.K., R.O.-S., N.T., A.M., T.H., H.N., S.K. performed research; T.K., R.O.S., and K.I. analyzed data; T.K., and K.I. wrote the paper; and K.I. supervised the entire project. All authors read and approved the final manuscript.

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Kitamura, T., Okubo-Suzuki, R., Takashima, N. et al. Hippocampal function is not required for the precision of remote place memory. Mol Brain 5, 5 (2012). https://doi.org/10.1186/1756-6606-5-5

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  • DOI: https://doi.org/10.1186/1756-6606-5-5

Keywords

Molecular Brain

ISSN: 1756-6606