--- id: wiki-2026-0508-neuroplasticity title: Neuroplasticity category: 10_Wiki/Topics status: verified canonical_id: self aliases: [Neuroplasticity, Brain Plasticity, Synaptic Plasticity] duplicate_of: none source_trust_level: A confidence_score: 0.9 verification_status: applied tags: [neuroscience, plasticity, hebbian, ltp, critical-period, learning] raw_sources: [] last_reinforced: 2026-05-10 github_commit: pending tech_stack: { language: python, framework: brian2-pytorch } --- # Neuroplasticity ## 매 한 줄 - 신경가소성은 시냅스·회로 수준에서 경험에 따라 신경계 구조·기능이 변화하는 능력이며, LTP/LTD가 분자 기반이다. ## 매 핵심 - **Hebbian rule**: "fire together, wire together" — pre/post synaptic 동시 발화 시 시냅스 강화. - **LTP/LTD**: NMDA receptor 매개 Ca²⁺ → CaMKII (LTP, 강화) vs calcineurin (LTD, 약화). hippocampus CA1, cortex L2/3에서 잘 연구됨. - **Critical period**: 시각피질 monocular deprivation 효과는 어린 시기 강함. parvalbumin GABA 성숙이 닫힘 trigger. 성인기 reopen에 chondroitinase, fluoxetine, dark exposure. - **Adult plasticity**: motor learning, taxi driver hippocampus 부피 증가, training-induced cortical map remodeling. - **AI 연결**: STDP(spike-timing dependent plasticity)는 SNN 학습 규칙, BCNN의 Hebbian feature learning에 영감. ## 💻 패턴 ```python # STDP weight update rule import numpy as np def stdp(dt, w, A_plus=0.01, A_minus=0.012, tau_plus=20e-3, tau_minus=20e-3, w_max=1.0): if dt > 0: # post after pre → LTP dw = A_plus * np.exp(-dt / tau_plus) else: dw = -A_minus * np.exp(dt / tau_minus) return np.clip(w + dw, 0, w_max) ``` ```python # Hebbian learning in linear neuron (Oja's rule, normalized) import numpy as np def oja_update(w, x, y, lr=0.01): return w + lr * (y * x - y ** 2 * w) ``` ```python # LTP induction: theta-burst stimulation pattern generator def theta_burst(duration_s=2.0, burst_hz=5, pulses_per_burst=4, intra_hz=100): times = [] t = 0.0 while t < duration_s: for k in range(pulses_per_burst): times.append(t + k / intra_hz) t += 1 / burst_hz return times ``` ```python # Synaptic scaling (homeostatic plasticity) import numpy as np def synaptic_scaling(W, target_rate, actual_rate, tau=1000.0): factor = target_rate / (actual_rate + 1e-6) return W * (1 + (factor - 1) / tau) ``` ```python # Brian2: STDP synapse simulation from brian2 import * G = NeuronGroup(2, "dv/dt = -v/(10*ms) : 1", threshold="v>1", reset="v=0") S = Synapses(G, G, """w : 1 dApre/dt = -Apre/(20*ms) : 1 (event-driven) dApost/dt = -Apost/(20*ms) : 1 (event-driven)""", on_pre="""v_post += w Apre += 0.01 w = clip(w + Apost, 0, 1)""", on_post="""Apost -= 0.012 w = clip(w + Apre, 0, 1)""") S.connect(i=0, j=1) ``` ```python # Cortical map plasticity index from receptive field overlap import numpy as np def map_plasticity(rf_pre, rf_post): overlap = np.minimum(rf_pre, rf_post).sum() / np.maximum(rf_pre, rf_post).sum() return 1 - overlap # higher = more remodeling ``` ```python # BDNF-dependent plasticity: serum BDNF as biomarker proxy def plasticity_score(bdnf_ng_ml, exercise_min_week, sleep_hr): # toy index, not clinical return 0.4 * bdnf_ng_ml / 30 + 0.3 * min(exercise_min_week, 300) / 300 + 0.3 * min(sleep_hr, 8) / 8 ``` ## 매 결정 기준 - **개입 시기**: critical period 진행 중이면 sensory restoration(eg. amblyopia patching) 효과 큼. - **약리 보조**: 성인 plasticity 재개에 SSRI(fluoxetine), tDCS, aerobic exercise(BDNF↑). - **학습 설계**: spaced repetition(LTP consolidation), sleep 보장(systems consolidation). - **연구 모델**: in vitro slice → LTP/LTD 측정. in vivo two-photon → spine turnover. ## 🔗 Graph - 관련: [[Neurorehabilitation-Post-Stroke]], [[Neurodevelopmental-Disorders]], [[Neuroprosthetics-Development]], [[Hebbian-Learning]] ## 🤖 LLM 활용 - 학습 곡선 데이터에서 plasticity phase 추정(initial vs consolidation). - 논문 요약: LTP 분자 경로 다이어그램 생성. - 실험 설계 review(빠진 control 식별). ## ❌ 안티패턴 - "성인 뇌는 변하지 않는다" 신화 인용. - STDP를 단순 Hebbian과 동일시(타이밍 차이 핵심). - BDNF 보조제 임의 권고(증거 부족). ## 🧪 검증 - LTP: fEPSP slope baseline 대비 +30% 30분 이상. - 행동: motor task 학습률, cortical map fMRI pre/post. ## 🕓 Changelog - 2026-05-08 Phase 1: 초안 자동 생성. - 2026-05-10 Manual cleanup: 본문 보강, STDP/Oja/Brian2 코드 추가, critical period reopen 약리 반영.