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// presynapse.md
Expansions and modulations:
- is expanded and developed by: AXON
- is tuned by: ORGANISM, organs, modules
- expands and tunes: PRE_VGG
- develops _Ca2, _Rrp
Introduction:
The presynaptic bouton releases neurotransmitter and gathers evidence about whether that release was worth strengthening and worth sustaining. Its behavior unfolds across two DAY contexts and the NIGHT scope.
During DAY, during AP — the bouton releases neurotransmitter. The amount released depends on:
- residual calcium from recent spikes (the fast trace), which sets the release drive;
- the two retrograde messages from the postsynapse — retro_eCB brakes the drive (the postsynapse is over-driven), retro_NO will later confirm that release reached a responsive target;
- the availability of both fuel and vesicles — release proceeds only if budget covers the cost and the readily-releasable pool is non-empty. These two shortfalls are read differently: a fuel shortfall on a succeeding release is evidence the bouton needs more endurance; an empty pool with fuel to spare is ordinary short-term depression.
During DAY, during NOT_AP — the bouton consolidates and recovers. With no spike to release, it:
- receives what arrived — latches the retrograde messages, refills its budget from astrocytic lactate and arrived axonal shipment (contested supply);
- maintains its traces — accumulates eligibility toward a tag, and stabilizes that tag if dopamine has arrived (the bridge toward strength);
- recovers its readily-releasable pool from the private reserve, between spikes (which is why high-frequency firing depletes faster than it recovers);
- lets its traces decay, closing the eligibility, endurance, and tagging windows.
During NIGHT — the bouton's ceilings are rewritten. Acting on the evidence gathered across the day, NIGHT raises the bouton's structure (active-zone capacity) where a validated tag accumulated, and its budget capacity (mitochondrial endurance) where fuel repeatedly interrupted a succeeding release. Both draw on the same finite material and energy shipped down the axon, so the bouton's two kinds of growth compete — and whatever is not maintained drifts back down.
PRESYNAPSE
include:
pre_vgcc.md
PRESYNAPSE
type: comprehension
_pre_fast_trace
_pre_possible_tag _pre_possible_intensity_tag
_pre_tag _pre_intensity_tag
_pre_dopamine
_eCB
_NO
_RRP
_NT
_pre_budget
_pre_astro_budget
_pre_axon_budget
_pre_endurance_need _pre_endurance_tag
// Intrication
// Scope
!DAY: INTRICATE [ scope: &ORGANISM.!DAY ]
!NIGHT: INTRICATE [ scope: &ORGANISM.!NIGHT ]
// Context
*AP: INTRICATE [ context: &SOMA.*AP ]
*TunPossible: INTRICATE [ context: &NEURON.*TunPossible ]
// Tub
_NT: INTRICATE [ tub: &ASTROSYNAPSE._NT ]
_ATP: INTRICATE [ tub: &ASTROCYTE._ATP ]
_eCB: INTRICATE [ tub: &POSTSYNAPSE._eCB ]
// Instantiation
// Context
*VcggIncrease: INSTANTIATE [ context: local ]
*VcggDecrease: INSTANTIATE [ context: local ]
*Ca2PrePreActiveDecrease: INSTANTIATE [ context: local ]
*Ca2PreActiveDecrease: INSTANTIATE [ context: local ]
*RrpPreActiveDecrease: INSTANTIATE [ context: local ]
*RrpPreActiveDecrease: INSTANTIATE [ context: local ]
// Tub
_Ca2: INSTANTIATE [ tub: local, full: 60x, act: 30x, empty: 0x ]
_Rrp: INSTANTIATE [ tub: local, full: 60x, act: 30x, empty: 0x ]
_Rp: INSTANTIATE [ tub: local, full: 60x, act: 30x, empty: 0x ]
_CaTracesHigh: INSTANTIATE [ tub: local, full: 60x, act: 30x, empty: 0x ]
_CaTracesMedium: INSTANTIATE [ tub: local, full: 60x, act: 30x, empty: 0x ]
_CaTracesLow: INSTANTIATE [ tub: local, full: 60x, act: 30x, empty: 0x ]
_Ca2FullDev: INSTANTIATE [ tub: local, full: 60x, act: 30x, empty: 0x ]
_RrpFullDev: INSTANTIATE [ tub: local, full: 60x, act: 30x, empty: 0x ] // serve al DEV
// Container
void: INSTANTIATE [ container: MAIN, scope: !DAY ]
void: INSTANTIATE [ container: TRACE, scope: !DAY ]
void: INSTANTIATE [ container: DECAY, scope: !DAY ]
void: INSTANTIATE [ container: RECOVER, scope: !DAY ]
void: INSTANTIATE [ container: ADJUST, scope: !DAY ] // Tuning
void: INSTANTIATE [ container: DEVELOP, scope: !NIGHT ]
// Expansion
_@pre_vgcc: INSTANTIATE [ tub: EXPAND [ comprehension: PRE_VGCC ], full: 10x, active: 5x, empty: 2x ] // PRE_VGCC, il tub _@pre_vgcc serve al tuning
MAIN
MAIN
type: container
// Emit NT
void: INSTANTIATE [ accumulator: NTreleaseLow, event: 12x, cost: 3x, context: *AP ] {
hypothesis: _Ca2 mediumness AND _Rrp mediumness AND NOT _ATP empty
action: [ _Rrp decrease, _NT increase, _ATP decrease ]
trace: None
}
void: INSTANTIATE [ accumulator: NTreleaseMedium, event: 9x, cost: 3x, context: *AP ] {
hypothesis: ( _Ca2 fullness AND _Rrp mediumness ) OR ( _Ca2 mediumness AND _Rrp fullness ) AND NOT _ATP empty
action: [ _Rrp decrease, _NT increase, _ATP decrease ]
trace: None
}
void: INSTANTIATE [ accumulator: NTreleaseHigh, event: 6x, cost: 3x, context: *AP ] {
hypothesis: _Ca2 fullness AND _Rrp fullness AND NOT _ATP empty
action: [ _Rrp decrease, NT increase, _ATP decrease ]
trace: None
}
TRACE
TRACE
type: container
within_scope: !DAY
// snippet: *AP
void: INCLUDE [ accumulator: TracesAccLow, event: act 3x, cost: act 3x ]
void: INCLUDE [ accumulator: TracesAccMedium, event: act 6x, cost: act 3x ]
void: INCLUDE [ accumulator: TracesAccHigh, event: act 10x, cost: act 3x ]
*AP
Ca2TracesAccuLow
type: accumulator
in_context: *AP
hypothesis: _Ca2 emptiness
action: [ _CaTraceLow increase ]
trace: None
Ca2TracesAccMedium
Ca2TracesAccMedium
type: accumulator
in_context: *AP
hypothesis: _Ca2 mediumness
action: [ _CaTraceMed increase ]
trace: None
Ca2TracesAccHigh
Ca2TracesAccumulationHigh
type: accumulator
in_context: *AP
hypothesis: _Ca2 fullness
action: [ _CaTraceHigh increase ]
trace: None
DECAY
MAIN
type: container
within_scope: !DAY
// snippet: NOT *AP
void: INCLUDE [ accumulator: eCBClearenceMedium, event: act 24x, cost: act 3x ]
void: INCLUDE [ accumulator: eCBClearenceLow, event: act 48x, cost: act 3x ]
void: INCLUDE [ accumulator: TracesClearance, event: act 30x, cost: act 3x ]
NOT *AP
eCBClearance
eCB dipende da POST. Tende a modulare l'entrata di Ca2 degli VGCC.
Qui non facciamo un flush di eCB, riduciamo ogni mezzo secondo (context) di un event di questo episodio.
eCBClearance: ( act: 24x ) # Slow
type: accumulator
in_context: NOT *AP
hypothesis: NOT _eCB empty
action: [ _eCB decrease ]
trace: None
Ca2TracesClearance
Qui facciamo un flush di CaTraceX. Deve essere fatto a valle del tuning.
Ca2TracesClearance
type: accumulator
in_context: NOT *TunPossible
hypothesis: NOT _CaTraceHigh empty
action: [ _CaTRaceHigh decrease ]
trace: None
hypothesis: NOT _CaTraceMedium empty
action: [ _CaTRaceMedium decrease ]
trace: None
hypothesis: NOT _CaTraceLow empty
action: [ _CaTRaceLow decrease ]
trace: None
RECOVER
RECOVER
type: container
within_scope: !DAY
// snippet: NOT *AP
£: INCLUDE [ accumulator: RPShuttleLow, event: act 24x, cost: act 3x ]
£: INCLUDE [ accumulator: RPShuttleMedium, event: act 48x, cost: act 3x ]
£: INCLUDE [ accumulator: RefillGlutamine, event: act 24x, cost: act 3x ]
NOT *AP
RPShuttleLow
This happens in the seconds loop, once per second.
The "Hard Bottleneck" State. Recruitment is throttled by a lack of signal, a lack of supply, or a lack of space. If even one of these "Near-Stop" conditions is met, the rate cannot exceed "Slow," regardless of the other two conditions.
Rate: 0.00 – 0.25
RPShuttleLow
type: accumulator
in_context: NOT *AP
hypothesis: _CaTraceLow fullness OR
_RP emptiness OR
_Rrp fullness
action: [ _RP decrease, _Rrp increase ]
trace: None
RPShuttleMedium
The "Sub-Optimal" State. The machinery is working, but it's held back by partial limitations. This covers cases where the signal is steady but the "piston" isn't firing at full speed, or where a high vacancy in the RRP (emptiness) forces a low signal to work a bit harder.
Rate: 0.50 – 0.97
RPShuttleMedium
type: accumulator
in_context: *AP
hypothesis: ( _CaTraceMedium fullness AND _RP mediumness AND _Rrp mediumness ) OR
( _CaTraceHigh fullness AND _RP mediumness AND _Rrp mediumness ) OR # signal boost
( _CaTraceMedium fullness AND _RP fullness AND _Rrp mediumness ) OR # supply boost
( _CaTraceMedium fullness AND _RP mediumness AND _Rrp emptiness ) # vacancy boost
action: [ _RP decrease, _Rrp increase ]
trace: None
RPShuttleHigh
The "High Performance" State. Multiple systems are optimized, but one is still at a "mediumness" level. This represents an active synapse that hasn't reached its absolute peak because either the supply is only 50% or the _Rrp isn't empty enough to create that "maximal vacuum" pull.
Rate: 1.25 – 1.94
RPShuttleHigh
type: accumulator
in_context: *AP
hypothesis: ( _CaTraceHigh fullness AND _RP fullness AND _Rrp mediumness ) OR # signal + supply
( _CaTraceHigh fullness AND _RP mediumness AND _Rrp emptiness ) OR # signal + vacancy
( _CaTraceMedium fullness AND _RP fullness AND _Rrp emptiness ) # supply + vacancy
action: [ _RP decrease, _Rrp increase ]
trace: None
RefillRPGlutamine
This happens in the minutes loop, once per minute, via the glutamine shuttle from the astrocyte. It is a two-step process across two cells.
Step 1 — astrocyte side The astrocyte has been accumulating cleared glutamate from the cleft since the last minutes-loop execution. Its glutamine synthetase enzyme converts that glutamate into glutamine, filling the Glutamine_pool. The fraction successfully converted per cycle is conversion_efficiency, which is set by glucose availability and boosted temporarily if the astrocyte calcium wave fired during the preceding seconds:
refill_RP = Glutamine_pool * conversion_efficiency Glutamine_pool = max(0.0, Glutamine_pool - refill_RP)
Step 2 — presynapse side
The glutamine crosses into the presynapse, where glutaminase converts it back into glutamate. That glutamate is immediately repackaged into vesicles and added to N_RP:
The asymmetry that makes depletion possible:
The chain reveals why sustained high-frequency firing eventually depletes the synapse even with all replenishment mechanisms running.
The RRP holds at most Max_RRP = 20 vesicles. At 20 Hz with strong Ca2, release can draw 2-4 vesicles per spike — potentially exhausting the RRP in under a second. The seconds loop can move vesicles from RP to RRP at a maximum rate of k_rec_fast = 5 /s, meaning at most 5 vesicles per second under ideal conditions. Release outpaces recruitment by roughly an order of magnitude during a burst.
The RP holds up to Max_RP = 200 vesicles — ten times the RRP. At sustained 20 Hz the RP can sustain firing for tens of seconds even after the RRP is repeatedly emptied, as long as recruitment keeps pace. But the minutes loop only refills N_RP once per minute at a rate limited by Glutamine_pool * conversion_efficiency. If glucose is low or the astrocyte wave has not fired, this replenishment may add only a fraction of what was consumed.
The result is a three-tier buffer with mismatched timescales:
RRP — depletes in seconds, refilled in seconds (fast but shallow) RP — depletes in minutes, refilled in minutes (deep but slow) Gln — depletes over bursts, refilled by glucose (slowest, astrocyte-dependent)
Each tier buys time for the one below it to respond. When all three are depleted simultaneously — which only happens under prolonged high-frequency firing with insufficient glucose — the synapse has no remaining buffer and goes silent until the minutes loop restores the Glutamine_pool.
ADJUST
ADJUST
// qui stiamo attivando e disattivando PRE_VGCC. Fra un massimo full e minimo empty (empty puo' non essere 0)
type: container
activity_scope: !DAY
// snippet: *TunPossible
@: INCLUDE [ contextor: VgccCheck, event: act 60x ]
// *VcggIncrease
@: INCLUDE [ accumulator: VcggIncrease, event:act 10x ]
// *VcggDecrease
@: INCLUDE [ accumulator: VcggDecrease, event:act 10x ]
*TunPossible
VgccCheck
Qui controlliamo che ci siano le condizioni per aumentare o diminuire l'attivazione di VGCC
VgccCheck
type contextor
in_context: *TunPossible
condition: _CaTraceHigh fullness
out_context: *VcggIncrease
condition: _CaTraceLow fullness
out_context: *VcggDecrease
*VcggIncrease
VcggIncrease
VcggIncrease
type: accumulator
in_context: *VcggIncrease
hypothesis:
action:
trace:
*VcggDecrease
VcggDecrease
VcggDecrease
type: accumulator
in_context: *VcggDecrease
hypothesis:
action:
trace:
DEVELOP
DEVELOP
type: container
activity_scope: !NIGHT
// snippet: *fixed
@: INCLUDE [ contextor: Ca2Check, event: act 60x ]
// snippet: *CaFullDecrease
@: INCLUDE [ accumulator: CaFullDecrease, event: act 12x, cost: act 3x ]
// snippet: *Ca2FullIncrease
@: INCLUDE [ accumulator: Ca2FullIncrease, event: act 12x, cost: act 3x ]
@: INCLUDE [ contextor: RrpCheck, event: act 60x ]
// snippet: *RrpFullDecrease
@: INCLUDE [ accumulator: RrpFullDecrease, event: act 12x, cost: act 3x ]
// snippet: *IncreaseRrpFull
@: INCLUDE [ accumulator: IncreaseRrpFull, event: act 12x, cost: act 3x ]
*fixed
Ca2Check
Tens Milliseconds Time Scale
Ca2Check
type: contextor
in_context: *fixed
condition: ( empty )
out_context: *CaFullDecrease
condition: ( full)
out_context: *Ca2FullIncrease
*CaFullDecrease
CaFullDecrease
DecreasePreCa2Full
type: accumulator
in_context: *CaFullDecrease
hypothesis: NOT ( full ) AND NOT ( empty )
action: [ increase, decrease]
trace: None
*Ca2FullIncrease
Ca2FullIncrease
IncreasePreCa2Full
type: accumulator
in_context: *Ca2FullIncrease
hypothesis: NOT ( full ) AND NOT ( empty )
action: [ increase, decrease]
trace: None
*fixed
RrpCheck
Tens Milliseconds Time Scale
RrpCheck
type: contextor
in_context: *fixed
condition: ( empty )
out_context: *RrpFullDecrease
condition: ( full)
out_context: *IncreaseRrpFull
*RrpFullDecrease
RrpFullDecrease
DecreasePreRrpFull
type: accumulator
in_context: *RrpFullDecrease
hypothesis: NOT ( full ) AND NOT ( empty )
action: [ increase, decrease]
trace: None
*RrpFullIncrease
RrpFullIncrease
RrpFullIncrease
type: accumulator
in_context: *RrpFullIncrease
hypothesis: NOT ( full ) AND NOT ( empty )
action: [ increase, decrease]
trace: None