- Home
- Knowledge Base
- References
Focused ultrasound-induced blood-brain barrier opening improves adult hippocampal neurogenesis and cognitive function in a cholinergic degeneration dementia rat model.
Shin J, Kong C, Lee J, Choi BY, Sim J, Koh CS, Park M, Na YC, Suh SW, Chang WS, Chang JW (2019) Focused ultrasound-induced blood-brain barrier opening improves adult hippocampal neurogenesis and cognitive function in a cholinergic degeneration dementia rat model. Alzheimers Res Ther 11(1):110. doi: 10.1186/s13195-019-0569-x
Objective: To investigate the decrease of adult hippocampal neurogenesis (AHN) in Alzheimer’s disease (AD).
Summary: This work studied the effect of FUS on AHN in a cholinergic degeneration rat model of dementia.
Usage: 192-IgG-SAP was injected bilaterally into the lateral ventricle (4 μl at a concentration of 0.63 μg/μl at a rate of 1 μl/min).
Related Products: 192-IgG-SAP (Cat. #IT-01)
Effect of medial septal selective and non selective lesions on exploratory behavior and recognition memory
Kruashvili L, Beselia G, Chkhikvishvili N (2019) Effect of medial septal selective and non selective lesions on exploratory behavior and recognition memory. Neuroscience 2019 Abstracts 336.01. Society for Neuroscience, Chicago, IL.
Summary: Investigation of cholinergic system and memory interaction has especially become the object of scientific attention due to the clinical and experimental data, in which the severity of dementia in Alzheimer’s disease (AD) was found to have a positive correlation with the extent of the cholinergic loss. The septum is connected to the hippocampus via the fimbria-fomix, which carries projections from the medial septum (MS), and the vertical limb of the diagonal band of Broca. These projections are predominantly cholinergic and GABAergic. Lesions of the fimbria-fomix, or electrolytic lesions of the MS, impair hippocampal- dependent learning and memory. The purpose of this study was to investigate ability to acquire and use spatial (or non-spatial) information as well as to habituate exploratory activity over time in sham-operated, electrolytic, neuro or immunotoxic MS lesioned rats. Methods: A total of 39 male rats were used. For electrolytic lesions a stainless steel was inserted in the MS. All injections were performed stereotaxically. Rats were individually given five 3-min sessions in the open field. All experiments were approved by the Animal Care and Use Committee of the Center and were in accordance with the principles of laboratory animal care. Results: Examination of the AChE stained sections showed that after injections of 192 IgG saporin into the MS, animals exhibited significantly less AChE staining in MS and hippocampus as compared to sections obtained from control animals. The MS electrolytic and ibotenic acid lesioned rats showed an increase in their exploratory activity to the objects and were impaired in habituating to the objects in the repeated spatial environment, rats with immunolesions of the MS did not differ from control rats. Electrolytic lesions of the MS disrupt spatial recognition memory, rats with immuno- or neurotoxic lesions of the MS were normal in detecting spatial novelty. The MS lesioned and control rats clearly reacted to the object novelty by exploring the new object more than familiar ones. Conclusions: MS is sufficient for spatial recognition, but is not sufficient for object recognition memory, the selective loss of septohippocampal cholinergic or noncholinergic projections does not disrupt the function of the hippocampus to a suffi cient extent to impair spatial recognition memory. Therefore, the present study demonstrates dissociation between the two major components (cholinergic and noncholinergic) of the septohippocampal pathway in exploratory behavior assessed in the open field.
Related Products: 192-IgG-SAP (Cat. #IT-01)
How to stimulate: Basal forebrain DBS parameters to restore the attentional performance of rats with cholinergic losses
Nazmuddin M, Rao HA, Van Laar T, Sarter MF (2019) How to stimulate: Basal forebrain DBS parameters to restore the attentional performance of rats with cholinergic losses. Neuroscience 2019 Abstracts 377.10. Society for Neuroscience, Chicago, IL.
Summary: The degeneration of basal forebrain (BF) cholinergic neurons is an index of the severity of cognitive impairment in Alzheimer disease (AD) and Parkinson’s disease (PD). Moreover, in PD patients, gait and balancing deficits, and an increased propensity for falls have been attributed to cholinergic losses. Thus, Deep Brain Stimulation (DBS) of the BF has been considered a potential therapeutic intervention to improve cognition and movement control in these patients. However, efficacy of BF DBS in clinical populations has yet to be conclusively demonstrated. Likewise, the demonstration of beneficial effects of BF DBS in rodent models has been hampered by uncertainties about useful animal models and behavioral tasks and, importantly, a lack of consensus concerning DBS parameters (duration, frequency, current, intermittent versus continuous, prior and/or during task, etc.). Here we assessed various DBS parameters in rats with a partial loss of the cortical cholinergic input system. In rats, such cholinergic losses have been frequently demonstrated to impair the detection of cues during the performance of a Sustained Attention Task (SAT) and to attenuate performance recovery following a distractor challenge (dSAT). In PD patients with cholinergic losses, attentional impairments were also attributed to cortical and thalamic cholinergic losses (Kim et al., 2017). The attribution of SAT impairments to cholinergic losses is consistent with evidence showing that the detection of cues and associated attentional control parameters depend on cortical cholinergic signaling (e.g., Howe et al., 2017). Here, rats acquired the SAT, received infusions of the cholino-specific neurotoxin 192-IgG-saporin into the BF, and were implanted bilaterally with BF unipolar stimulation electrodes. Initial DBS parameters consisted of continuous high (130 Hz) versus low (20 Hz) frequency stimulation, intermittent (20-s ON at 80 Hz and 40-s OFF) stimulation, with pulse width and amplitude kept constant at 100 µs and 100 µA, respectively. We first assessed the effects of these DBS parameters on the behavior of rats in an open field space and then when administered during, or only prior to (for 1 hr), SAT and dSAT performance. Ongoing experiments indicate that these stimulation parameters are well tolerated as indicated by the absence of effects on locomotor and exploratory activity. We predict that BF DBS will be particularly effective in restoring attentional performance in the dSAT condition. If confirmed, this finding will suggest that demonstration of efficacy in patients will require measures indicating their attentional capacities in response to taxing performance challenges.
Related Products: 192-IgG-SAP (Cat. #IT-01)
Effects of an orexin-2 receptor agonist on attention in rats following loss of cortical cholinergic projections
Blumenthal SA, Maness EBL, Fadel JR, Burk JA (2019) Effects of an orexin-2 receptor agonist on attention in rats following loss of cortical cholinergic projections. Neuroscience 2019 Abstracts 418.06. Society for Neuroscience, Chicago, IL.
Summary: Deterioration to the basal forebrain cholinergic system (BFCS) is linked to age-related cognitive impairment, specifically to the pathology of Alzheimer’s disease (AD). Animals with BFCS damage perform poorly on learning, memory, and attention tasks, indicating cognitive deficits. The orexin neuropeptide system, comprised of two neuropeptides (orexin A and orexin B), has also been implicated in the cognitive decline associated with aging, likely due to the role of orexins in promoting attention. Two orexin receptor subtypes exist, orexin 1 (Ox1R) and orexin 2 (Ox2R). Studies have examined the effects of stimulation and blockage of both receptors together and Ox1R alone on attention; but no studies have examined the role of Ox2Rs in attention through the use of Ox2R agonists. Ox2Rs may be implicated in attentional processes and the loss of orexin neurons seen in age-related cognitive decline. In order to examine the role of Ox2Rs in attention following BFCS deterioration, the present study administered the Ox2R agonist, YNT-185, to rats given intrabasalis infusions of either saline (n = 12) or 192 IgG saporin (n=11), an immunotoxin which selectively destroys the BFCS. Animals received infusions of YNT-185 to the lateral ventricle (LV) in doses of 0, 1, 10, and 100nM across four separate sessions and performance was then assessed on a sustained attention task requiring discrimination between signal and non-signal trials through lever presses. The 100nM dose of YNT-185 improved attentional performance, as compared to the 0nM dose, for rats given the immunotoxin, but worsened performance for rats given saline lesions. YNT-185 may be efficacious in aiding attentional function in animals with vulnerable cholinergic systems but may lead to overexcitation for those with intact cholinergic function.
Related Products: 192-IgG-SAP (Cat. #IT-01)
Increased transplantation efficacy of mesenchymal stem cell by focused ultrasound and improvement of the spatial memory in the 192 IgG-saporin rat model
Lee J, Seo Y, Shin J, Kong C, Na Y, Chang W, Chang J (2019) Increased transplantation efficacy of mesenchymal stem cell by focused ultrasound and improvement of the spatial memory in the 192 IgG-saporin rat model. Neuroscience 2019 Abstracts 048.01. Society for Neuroscience, Chicago, IL.
Summary: Introduction: Stem cell therapy has been found to have therapeutic effects in neurodegenerative disease, but traditional transplant methods, such as parenchymal or intravenous injection, possess limitations like secondary injuries, infection, and low survival rate of stem cells in the brain. Meanwhile, recently the focused ultrasound(FUS) was found to have promising results regarding transplantation of stem cells into the rat brain. However, the mechanism of stem cell transplantation with FUS and possibility of cognitive recovery remain elusive. Therefore, this study investigates a possibility for non-invasive focused ultrasound use in stem cell transplantation into the brain of dementia rat model. Materials & methods: We divided rats into five groups: Normal, Lesion, Cell only, FUS + Cell, and FUS only. We used 192 IgG-saporin for degeneration of basal forebrain cholinergic neuron and it was injected into all rats except for the normal group. After a week, 5p mesenchymal stem cells (MSC: 3*106/200ul) were injected in the tail vein of all rats of the cell only and FUS + Cell group, and the FUS + Cell group received the FUS three hours before cell transplantation. FUS was applied with parameters of 0.25Mpa, 300s (Targeted hippocampal region: AP -3.5, ML ±2). And last, FUS only group was received only FUS without any treatment. Five weeks after transplantation, rats performed the Morris water maze test. Results: MSC were detected in both cell only and FUS + Cell group of the hippocampus region. After comparing FUS+MSC & cell only rats, it was confirmed that FUS increases MSC homing in the sonicated rat’s brain. In addition, the most effective memory restoration occurred in the FUS + Cell group. Moreover, the FUS + Cell group exhibited better recall of the platform position than the other groups. And FUS only group did not recover. Conclusion: Noninvasive FUS can increase the efficacy of stem cell delivery. And memory impairment due to cholinergic denervation can be effectively improved by cell transplantation with FUS. The results of this study suggest possibility of stem cell homing and therapeutic effects of the FUS in dementia rat model. However, further study regarding the function of stem cells transplanted in the brain and a more detailed mechanism of stem cell homing by FUS is needed.
Related Products: 192-IgG-SAP (Cat. #IT-01)
Sign-trackers deploy perceptual, but not cholinergic-attentional, mechanisms to respond to salient cues
Phillips KB, Avila C, Sarter M (2019) Sign-trackers deploy perceptual, but not cholinergic-attentional, mechanisms to respond to salient cues. Neuroscience 2019 Abstracts 331.10. Society for Neuroscience, Chicago, IL.
Summary: Sign-trackers (STs) attribute incentive value to stimuli that predict food and drug rewards and therefore have emerged as a model for studying vulnerability for addiction-like behaviors. Relative to goal-trackers (GTs), who do not imbue discrete predictive stimuli with motivational value, STs also show a reduced capacity for engaging forebrain cholinergic signaling for the processing of behaviorally significant and attention-demanding cues. The greater power of Pavlovian drug cues in STs has been attributed in part to their relatively poor attentional control of such cues. However, when tested in an operant Sustained Attention Task (SAT), STs exhibit only a minor impairment in hit rates but, more robustly, unstable performance over time. These observations raised the question as to the neuro-behavioral or -cognitive mechanisms via which STs perform the SAT. Male and female STs were trained on SAT. The SAT requires the reporting of cues as well as non-cue events via separate levers, yielding four response categories (hits and misses, and correct rejections and false alarms). After reaching criterion, half of STs received bilateral infusions of the cholino-selective neurotoxin 192-IgG saporin while the remaining STs received sham-lesions. Following recovery, performance was assessed on the SAT and a version of SAT incorporating a flashing house light distractor (dSAT). Goal-directed (or top-down) attention is thought to maintain and recover performance during dSAT and mediated via increases in cortical cholinergic activity. In STs, neither SAT nor dSAT performance depended on the integrity of the cholinergic system. We therefore hypothesized that STs perform the SAT using model-free, non-attentional mechanisms, perhaps relying largely on trial-biased perceptual processes to detect salient cues. To test this hypothesis, separate STs and GTs were trained on SAT. The salience of the cue light relative to the house light was varied across operant chambers. In STs, greater perceptual sensitivity reductions were observed as a function of relatively weaker cue salience. In contrast, GTs’ perceptual sensitivity did not relate to cue salience. Associated with their relatively unresponsive cholinergic system, STs rely on perceptual mechanisms, rather than attentional mechanisms, to perform the SAT. The relative absence of (top-down) attentional control of behaviorally significant cues, combined with a propensity to attribute incentive value to such cues, renders STs less likely to reject such cues from guiding their behavior and engaging in alternative action.
Related Products: 192-IgG-SAP (Cat. #IT-01)
Dissociable attentional effects of dopaminergic and cholinergic lesions to the anterior cingulate cortex
Clement MK, Pimentel CS, Swaine JA, Pimentel AJ, Hutchins D, McGaughy JA (2019) Dissociable attentional effects of dopaminergic and cholinergic lesions to the anterior cingulate cortex. Neuroscience 2019 Abstracts 418.11. Society for Neuroscience, Chicago, IL.
Summary: Prior work from our lab has shown that excitotoxic lesions to the anterior cingulate cortex (ACC) impairs the ability of rats to filter certain types of distracting stimuli (Newman and McGaughy 2011). Specifically, rats with lesions of the ACC cannot filter distractors that have been made salient through pairing with reinforcement. In contrast, these same subjects can filter distracting stimuli that have not been predictive of reward. The present study investigates the effects of neuromodulator specific lesions of the same region to determine how specific neuromodulators contribute to the attentional function of ACC. Cholinergic or dopaminergic deafferentation of the ACC was achieved using either 192 IgG saporin (n=10) or dopamine transporter saporin (n=10). Lesions were restricted to the rostral portion of the area and did not spread to nearby prefrontal sub-regions e.g prelimbic cortex. After lesioning, subjects were tested in an attentional set-shifting task (Birrell and Brown 2000). While both cholinergic and dopaminergic lesions increased distractibility, these deficits were not as severe as those produced after excitotoxic lesions (n= 8). In contrast to excitotoxic lesions, both cholinergic and dopaminergic lesions also impeded formation of an attentional set. Because dopaminergic lesions produced impairments in many stages of the tasks, we hypothesized that these subjects had a more general impairment in stimulus processing. In order to address these broader processing impairments, we analyzed the data to determine whether lesioned rats showed more sensitivity to novel stimuli, or made more perseverative errors. The implications of these data for understanding the unique contributions of acetylcholine and dopamine to attentional processing in the ACC will be discussed.
Related Products: 192-IgG-SAP (Cat. #IT-01), Anti-DAT-SAP (Cat. #IT-25)
Medial septum cholinergic signaling regulates gastrointestinal-derived vagus sensory nerve communication to the hippocampus
Suarez AN, Liu CM, Cortella AM, Noble EN, Kanoski SE (2019) Medial septum cholinergic signaling regulates gastrointestinal-derived vagus sensory nerve communication to the hippocampus. Neuroscience 2019 Abstracts 601.19. Society for Neuroscience, Chicago, IL.
Summary: The vagus nerve delivers bi-directional communication between feeding-relevant gastrointestinal (GI) signals and the brain. Vagal sensory-mediated GI satiation signals, including gastric distension and intra-gastric nutrient infusion, activate neurons in the hippocampus (HPC). Recent work from our lab revealed that selective GI-derived vagal sensory signaling is required for HPC-dependent episodic and visuospatial memory, effects accompanied by reduced dorsal HPC (dHPC) expression of neurotrophic and neurogenic markers. To investigate the neural pathways mediating gut regulation of hippocampal-dependent memory, here we investigate the hypothesis that GI-derived signals communicate to dHPC neurons via cholinergic input from the medial septum, a memory-promoting pathway that is vulnerable to disruption in various degenerative dementia diseases. To explore this putative gut-to-brain pathway, we administered 192IgG-saporin, a neurotoxin that selectively kills cholinergic neurons via apoptosis, in the medial septum to determine whether septal cholinergic neurons regulate vagally-mediated neuronal activation in dHPC. Results revealed that elimination of cholinergic neurons in the MS reduced peripherally-administered cholecystokinin (CCK)-induced c-Fos expression in the dHPC, suggesting that cholinergic inputs from the MS transmit GI-derived signaling to the dHPC. Consistent with this interpretation, dHPC protein expression of vesicular acetylcholine transporter (VAChT), which promotes memory function and acetylcholine release without disrupting other co- released molecules, was significantly reduced in rats with GI-specific vagal sensory ablation via nodose ganglion injections of CCK conjugated to saporin. Collectively these results suggest that GI-derived vagal sensory signaling infuences memory function via enhancement of MS cholinergic signaling to the dPHC.
Related Products: 192-IgG-SAP (Cat. #IT-01), CCK-SAP (Cat. #IT-31)
The role of subcortical hippocampal inputs in contextual memory formation
Grayson VS, Han Y, Guedea AL, Jovasevic V, Gao C, Apkarian A, Radulovic JM (2019) The role of subcortical hippocampal inputs in contextual memory formation. Neuroscience 2019 Abstracts 786.03. Society for Neuroscience, Chicago, IL.
Summary: The role of cortical efferents to the hippocampus in the formation of episodic-like memory is well established, however, less is known about the contribution of subcortical memory circuits to memory. In the present study, we studied the roles of several subcortical inputs into the dorsal hippocampus in mouse models of contextual fear conditioning, extinction, and reinstatement. Fear conditioning was induced by a single exposure of mice to a context followed by foot shock. Subsequently, mice were exposed to daily extinction trials. After significant reduction of freezing, indicating successful extinction, mice were exposed to a brief reminder shock and re-tested in the conditioning context. Circuit manipulations were performed by chemogenetic silencing with the inhibitory designer receptor exclusively activated by designer drugs (DREADD) hM4(Gi) or targeted cholinergic depletion induced by 192 IgG-saporin, at different stages of fear conditioning, extinction, and reinstatement. We identified projection- and neurotransmitter-specific roles of discrete circuits, indicating complex regulation of fear-inducing memories by subcortical afferents.
Related Products: 192-IgG-SAP (Cat. #IT-01)
Selective loss of septohippocampal cholinergic projections is associated with more circuitous homeward progressions
Osterlund JR, BLackwell AA, Lipton M, Castillo V, Kartje GL, Tsai S-Y, Wallace DG (2019) Selective loss of septohippocampal cholinergic projections is associated with more circuitous homeward progressions. Neuroscience 2019 Abstracts 789.11. Society for Neuroscience, Chicago, IL.
Summary: Rodents rely on self-movement cues as a source of information to maintain spatial orientation during exploration. The vestibular system provides a source of self-movement cues that are processed by the septohippocampal cholinergic system, and when damaged, disruptions in movement organization are observed. The current study examined the effects of medial septum infusion of 192 IgG-saporin on movement organization during a single exploratory session that limited rats to using only self-movement cues. Rats organize their exploratory behavior into stops and progression. Although stops occur throughout the environment, they tend to cluster within a restricted area indicative of home base establishment. In the current study, movement organization characteristics and home base stability were similar between the lesion and sham groups. However, the lesion group exhibited greater path circuity during progressions returning to the home base. Increases in path circuitry have been implicated in spatial disorientation, indicating a role for medial septum cholinergic projections in processing self-movement cues to maintain spatial orientation. These results provide a foundation for future work to investigate the efficacy of interventions that enhance neuroplasticity within the septohippocampal cholinergic system.
Related Products: 192-IgG-SAP (Cat. #IT-01)