Don't Think I Ever Posted This Kim Anywhere? I Might Have On Instagram But I Can't Recall. This Is Based

im starting a collection

(☞ ͡° ͜ʖ ͡°)☞ DISCO ELYSIUM  ▴  11/–

I'm going back to my playful colour era, never really realised I left it until my paintings became a little stale. Anyway, please say yes she's really over here like 🥺👉👈

IT'S DONE

94 pages containing most of my Disco Elysium Fanart alll made up and pretty for you.

You can get it here on my Ko-fi! :)

[If you are here for the Disco Sapphics - this pdf does not include any of that since it's going to be it's own thing. Follow here or on Ko-fi to get notified once it's done!]

Feel free to use the cover in every day conversation btw. I know I have

Compilation of random Kim’s lines where he sounds a little more upbeat than usual (amused, excited, curious, snorting, etc.) — 6 min

The Locust City video has been taken down by ZA/UM. I’ve never been more angry.

BE VIGILANT. I LOVE YOU.

my favourite 7/10 sharpshooter

Memory Hacks: Neuroscience Behind Efficient Memory Techniques

Memory is an elusive neural process concerning the interaction of various parts of the brain, neural tracts, and neurotransmitters. Considering popular memory hacks, we have learned how such techniques used structures and mechanisms of the brain in their own way to make the information more available. Let's carefully look into eight memory hacks and why they work on a neuroscientific level.

The Memory Palace Technique and the Hippocampus: The so-called Memory Palace, or method of loci, in its overall functioning relies on the brain's spatial memory system, enlisting primarily the hippocampus. The hippocampus is placed within the medial temporal lobe and plays a vital role in producing and retrieving spatial and episodic memories. This particular area was more significant for our ancestors with regard to orientation and mapping of their environment, a skill directly related to survival. When you visualize putting things in places you know well, your hippocampus is associating the spatial memory of that place with more abstract information you want to remember. Such an association results in a strong memory trace, since spatial memory is more robust and resilient. The technique also engages the parahippocampal gyrus, which processes visual-spatial context, thereby facilitating retrieval by mentally "walking" through the familiar place.

The Spacing Effect and Synaptic Plasticity: The spacing effect, otherwise known as spaced repetition, is based upon synaptic plasticity, which means the strengthening of synapses through repeated activity. So, when something is reviewed over a longer period of time, it strengthens the neural pathways related to that memory. This reinforcement happens during consolidation, a process heavily supported by the hippocampus and prefrontal cortex. Each time the information is revisited, it causes long-term potentiation-a process whereby repeated stimulation of neurons strengthens synaptic connections. LTP simply makes it easier for those neurons involved in that memory to fire together simultaneously, therefore creating a stronger memory pathway. Such periodic reinforcement will enable the memory to move from short-term to long-term storage and thus set it firmly in the neocortex for long-term recall.

Visualization and Multi-Sensory Memory Encoding: Visualization techniques capitalize on multi-sensory memory encoding to engage not just the hippocampus but also the occipital lobe for visual processing and the fusiform gyrus involved in object and face recognition. Transposing these more abstract pieces of information into vivid mental images through visualization naturally creates a deeper sensory trace, which the brain favors and finds easier to remember. When we visualize, neurons in the visual and sensory cortex fire in patterns that resemble actual sensory experience; detaied and richly encoded memory representations are thus built. This multisensory approach will include the amygdala if there is an emotional component of the visualization, thus forming emotionally laden memories which are even easier to recall because of their strength in memory consolidation.

Teaching or Explaining and the Role of Elaborative Rehearsal: Teaching others or explaining increases retention due to elaborative rehearsal, where the new information is related to the knowledge that already exists. This strongly engages the prefrontal cortex, an area involved in comprehension and planning, along with association cortices that integrate sensory information from multiple regions. Every time you teach something or explain it, you are retrieving information and reorganizing it in your own words. This practice not only reinstates the neural circuits transporting the information but also allows neuroplasticity to be reinforced through reshaping and strengthening synapses participating in this retrieval process, hence making that memory more accessible later. Teaching arouses the dorsolateral prefrontal cortex and, in turn, enhances both comprehension and memory encoding.

Mnemonics, Rhymes, and the Temporal Lobes: Mnemonics, especially those with a rhyme or rhythm, enlist auditory processing centers in the temporal lobes. The auditory cortex of the brain is highly tuned for patterns in sound; for this reason rhythm and rhyme are memorable. Angular gyrus and superior temporal gyrus, both implicated in language processing, are activated when mnemonics are used to encode information as sequences or patterns. The repetition within mnemonics and rhymes strengthens sequential memory by evoking the ability with which the brain is particularly adept: remembering information in order. This systematic encoding, thus, has the potential to support the linkage of abstract information with identifiable auditory patterns and enhance recall. Moreover, the cingulate gyrus, involved in the distribution of attention, could further enhance this by focusing and encoding these rhythmic patterns as memories of items.

Diet, Neurotransmitters, and Brain Health: Nutrition can have a variety of impacts on memory and cognition, from neurotransmitters to structure. Some nutrients are precursors to neurotransmitters studied as influencing cognition. Acetylcholine is a neurotransmitter associated with learning and memory and whose synthesis depends on choline intake. Food containing high amounts of choline, such as egg and fish, should provide an adequate supply for the synthesis of acetylcholine in the basal forebrain. Omega-3 fatty acids are considered essential for neuronal membrane health and ensure that signals between neurons are well transmitted. Antioxidants from fruits and vegetables reduce oxidative stress in the brain, which protects against cognitive decline and promotes neuroplasticity. Adequate nutrition maintains neurotransmitter function & structural integrity in memory regions such as the hippocampus and prefrontal cortex, promoting overall cognitive resilience and facilitating higher memory capacity.

Source: Memory Hacks: Neuroscience Behind Efficient Memory Techniques