Targeted memory reactivation (TMR) is a method whereby cues associated with previous learning are used to externally reactivate aspects of this learning. Research findings demonstrate that TMR can be a useful tool to enhance memory consolidation during sleep in both animals and humans, especially in the declarative/spatial domain. Neurocognitive processing during sleep with covert cueing via auditory or olfactory stimulation can benefit memory storage. These beneficial effects on memory consolidation during sleep are associated with the activation of memory-related brain areas. The purpose of the present review is to provide a short overview of the findings of studies that adopted the TMR method of sleep-dependent memory consolidation and to suggest the potential applications of TMR in variable areas.
Animals ; Brain ; Cues ; Humans ; Learning ; Memory Consolidation* ; Memory* ; Methods

Sleep is well known to be important to health and well-being, creativity, memory consolidation, and cognitive functions. However, sleep disorder patients sometimes had some limitation to get proper diagnosis and treatments. Now we live in an era of big change, so called the Fourth Industrial Revolution, which is characterized by mobile internet connectivity and artificial intelligence. Sleep medicine also started to change to patients-centered medicine with technical enhancement. To date, lots of smartphone applications and wearable device for monitoring sleep have appeared but not been validated enough against polysomnography. As another topic, big data receives lots of attention among sleep specialists. It is believed that big data would provide the basis of personalized healthcare. Here, we will discuss about new trend of sleep medicine involving mobile health such as telemedicine, smartphone, wearable device, and big data.
Artificial Intelligence ; Cognition ; Creativity ; Delivery of Health Care ; Diagnosis ; Humans ; Internet ; Memory Consolidation ; Polysomnography ; Sleep Wake Disorders ; Smartphone ; Specialization ; Telemedicine

Liriopogons (Liriope and Opiopogon) species are used as a main medicinal ingredient in several Asian countries. The Liriopes Radix (tuber, root of Liriope platyphylla) has to be a promising candidate due to their source of phytochemicals. Steroidal saponins and their glycosides, phenolic compounds, secondary metabolites are considered of active constituents in Liriopes Radix. Spicatoside A, a steroidal saponin, could be more efficacious drug candidate in future. In this review, we summarized the available knowledge on phytochemical and pharmacological activities for spicatoside A. It significantly suppressed the level of NF-κB, NO, iNOS, Cox-2, IL-1β, IL-6 and MAPKs in LPS-stimulated inflammation. The production of MUC5AC mucin was increased. MMP-13 expression was down-regulated in IL-1β-treated cells and reduced glycosaminoglycan release from IL-1α-treated cells. The neurite outgrowth activity, PI3K, Akt, ERK1/2, TrkA and CREB phosphorylation and neurotropic factors such as NGF and BDNF were upregulated with increased latency time. It also showed cell growth inhibitory activity on various carcinoma cells. From this, spicatoside A exerts anti-inflammation, anti-asthma, anti-osteoclastogenesis, neurite outgrowth, memory consolidation and anticancer activities. Further studies are needed on spicatoside A in order to understand mechanisms of action to treat various human diseases.
Asian Continental Ancestry Group ; Brain-Derived Neurotrophic Factor ; Glycosides ; Humans ; Inflammation ; Interleukin-6 ; Memory Consolidation ; Mucins ; Nerve Growth Factor ; Neurites ; Phenol ; Phosphorylation ; Phytochemicals ; Saponins

Animals ; Cell Nucleus ; enzymology ; Drosophila Proteins ; genetics ; metabolism ; Drosophila melanogaster ; Extracellular Signal-Regulated MAP Kinases ; genetics ; metabolism ; Long-Term Potentiation ; physiology ; MAP Kinase Signaling System ; physiology ; Memory Consolidation ; physiology ; Neurons ; cytology ; enzymology

Although extensively studied, the exact role of sleep in learning and memory is still not very clear. Sleep deprivation has been most frequently used to explore the effects of sleep on learning and memory, but the results from such studies are inevitably complicated by concurrent stress and distress. Furthermore, it is not clear whether there is a strict time-window between sleep and memory consolidation. In the present study we were able to induce time-locked slow-wave sleep (SWS) in mice by optogenetically stimulating GABAergic neurons in the parafacial zone (PZ), providing a direct approach to analyze the influences of SWS on learning and memory with precise time-windows. We found that SWS induced by light for 30 min immediately or 15 min after the training phase of the object-in-place task significantly prolonged the memory from 30 min to 6 h. However, induction of SWS 30 min after the training phase did not improve memory, suggesting a critical time-window between the induction of a brief episode of SWS and learning for memory consolidation. Application of a gentle touch to the mice during light stimulation to prevent SWS induction also failed to improve memory, indicating the specific role of SWS, but not the activation of PZ GABAergic neurons itself, in memory consolidation. Similar influences of light-induced SWS on memory consolidation also occurred for Y-maze spatial memory and contextual fear memory, but not for cued fear memory. SWS induction immediately before the test phase had no effect on memory performance, indicating that SWS does not affect memory retrieval. Thus, by induction of a brief-episode SWS we have revealed a critical time window for the consolidation of hippocampus-dependent memory.
Animals ; Cues ; Electroencephalography ; Electromyography ; Evoked Potentials, Motor ; physiology ; Fear ; psychology ; Glutamate Decarboxylase ; metabolism ; Hippocampus ; physiology ; Light ; Luminescent Proteins ; genetics ; metabolism ; Maze Learning ; physiology ; Memory Consolidation ; physiology ; Mice ; Mice, Inbred C57BL ; Mice, Transgenic ; Sleep Deprivation ; Sleep, Slow-Wave ; physiology ; Time Factors ; Vesicular Inhibitory Amino Acid Transport Proteins ; genetics ; metabolism