We seem to forget that the mind is physical.
Executive circuits, memory centers, and analytical regions are extremely energy-intensive. The brain consumes 20% of the body's energy. SynapX optimises it.
We seem to forget that the mind is physical. Energy means metabolic waste - oxidative stress, neuroinflammation, and nutrient deficits are the cause of burnout, delayed thinking, interlobal dissconnect.
Without targeted cognitive enhancement, peak cognition is unsustainable, even for the most disciplined minds.
High-performing minds function differently according to their occupation.
Occupation shapes cognition by selectively activating different neural networks: founders rely heavily on prefrontal executive circuits, medical students on hippocampal–memory systems, and engineers on analytical–parietal pathways. Each pattern produces its own metabolic demands and vulnerabilities.
One can target each neural circuit's neuroinflammatory relief, blood flow, and oxidative health.
For example, heavy prefrontal lobe use in founders increases PFC-specific oxidative stress, which we buffer by anthocyanins; these compounds cross the blood–brain barrier and suppress NF-κB–driven inflammation directly inside PFC tissue, increasing your speed of synaptic transmission.
We optimise neural circuits for ambitious minds to perform at full capacity - personalised protocols according to your body, and your profession.
Founders.
Mental stamina │ Reward circuit optimisation │ Stress Resilience
Executive decision-making, planning, complex problem-solving, pattern recognition.
Relies on PFC (Prefrontal Cortex), DLPFC (Dorsolateral Prefrontal Cortex), OFC (Orbitofrontal Cortex), Hippocampus.
SynapX enhances executive control, reduces oxidative load, and reinforces motivation circuitry. We optimise:
Mental stamina: high ATP production causes metabolic waste accumulation in PFC tissue. SynapX supports PFC-specific mitochondrial renewal, blood flow, and BBB-crossing free radical neutralising antioxidants.
Reward/ Motivation circuit: high cognitive load increases neuronal firing & ROS, functionally desensitising dopamine receptors and dopamine signal transduction. SynapX analyses your blood glucose levels, energy spikes & lows, work routine, and crafts personalised dopamine starvation programs for optimised sensitivity.
Stress resilience: chronic cortisol suppresses hippocampal neurogenesis, inhibiting memory circuits, synaptic plasticity, enhances amygdala hyperactivity, leading to heightened emotional responses and loss of stability. SynapX targets personalised vagal activation for cortisol reduction, times high-focus work blocks according to your cortisol levels, triggers vagal restoration micro-breaks when detecting cortisol spikes, and promotes BDNF blood flow for efficient cortisol metabolism.
Doctors.
Heavy memorization | Rapid recall | High-pressure focus
Heavy memorization: encoding vast amounts of medical knowledge places extreme metabolic demand on hippocampal–PFC circuits, producing ROS and reducing synaptic plasticity over time. SynapX monitors your neural study patterns, shift schedules, and cognitive load, then delivers timed antioxidant supplementation, memory consolidation micro-breaks, and hippocampal-directed neuro-nutrition, ensuring that neurons remain efficient and long-term encoding is maximised.
Rapid recall: high-stakes clinical decisions require instant retrieval of relevant information from hippocampal and PFC networks. Under stress, ROS accumulation and microglial activation slow signal transmission, impairing recall. SynapX tracks your alertness cycles, work intensity, and real-time cognitive performance, then implements recall training sprints, adaptive cue exposure, and timed tyrosine-based precursors to maintain fast, accurate memory retrieval during critical moments.
High-pressure focus: sustained attention during emergencies or complex procedures engages PFC–ACC–insula networks, which are vulnerable to metabolic overload, cortisol spikes, and oxidative stress. SynapX measures your physiological stress markers, work rhythm, and sensory input patterns, triggering micro-focus sessions, vagal restoration exercises, and attention-targeted nootropic dosing, keeping executive control intact and distractions suppressed under extreme cognitive load.
Engineers.
Sustained focus | Complex problem-solving | 3D visualisation
Sustained focus: focus is a balance of excitatory (forward) and inhibitory (resist) pathways that create a dynamic balance for sustainable attention and flow.
Sustained focus: Maintaining attention over long coding sessions, simulations, or design problem-solving relies on a dynamic balance between excitatory glutamatergic signaling and inhibitory GABAergic control in DLPFC–PFC–ACC networks. High-frequency firing generates ROS and depletes ATP, impairing synaptic reliability and attention. SynapX keeps excitatory-inhibitory balance stable and flow states sustained under extreme cognitive load through tracking and personalised neuro-nutrition for timed GABA & glutamate precursors.
Complex problem-solving: analytical reasoning engages high-frequency PFC–ACC synaptic firing and NMDA receptor-mediated plasticity for multi-step logical integration. ROS accumulation, cytokine signaling (IL-6, TNF-α), and metabolic stress impair NMDA receptor function and dendritic spine stability, slowing computation and error detection. SynapX tracks task complexity, work rhythm, and stress markers, implementing problem decomposition routines, adaptive challenge bursts, tyrosine precursors for dopamine support, and micro-dosed neurotrophics, maintaining plasticity, firing efficiency, and rapid analytical reasoning during high-stakes projects.
3D visualization: spatial reasoning, CAD modeling, and multi-dimensional design rely on parietal–cerebellar–hippocampal loops where calcium-dependent synaptic transmission encodes spatial representations. Glutamate excitotoxicity, metabolic overload, and oxidative stress disrupt calcium signaling, reducing mental rotation accuracy and working memory. SynapX applies calcium-buffering nutrients, synaptic protein support, and spatial memory chunking protocols to preserve high-resolution 3D mental modeling. By stimulating parietal–hippocampal connectivity, SynapX improves anticipatory spatial reasoning, letting engineers mentally simulate complex structures before building.
