The aging brain doesn't passively decay—it executes a structured, multi-phase eviction protocol. Current evidence supports active clearance of senescent neural stem cells and neuroblasts via NK cell recruitment mediated by the senescence-associated secretory phenotype (SASP)1. But for mature neurons, the mechanism shifts from physical removal to functional isolation.

The Hypothesis: A dual-system emerges with age. First, a targeted immune-clearance tier removes senescent precursors to prevent oncogenic transformation and preserve niche function. Second, a metabolic efficiency tier selectively downregulates and structurally isolates mature neurons that violate energy constraints, without necessarily killing them immediately. This is eviction via silencing, not immediate execution.

Mechanistic Bridge: Senescent glial cells drive neuroinflammation via SASP, activating complement and microglial phagocytic signaling2. But this same inflammatory environment can trigger synaptic stripping—microglial-mediated removal of synapses from otherwise intact neurons3. A neuron with broken mTORC1 nutrient sensing4 and failed proteostasis becomes metabolically expensive to maintain. The system doesn't kill it outright; it first silences it by stripping its connections, reducing its network influence and energy draw.

Testable Predictions:

1. Spatial Specificity: In aging hippocampi, neuromelanin-rich (metabolically compromised) neurons5 will show increased microglial contact and synaptic loss before tau pathology or death, compared to neuromelanin-poor neurons.
2. Temporal Decoupling: Synaptic stripping markers (complement C1q, microglial phagocytic receptors) will correlate with metabolic dysfunction (AMPK activity, mTORC1 persistence) in regions undergoing "normal" age-related volume loss, but not in early Alzheimer's, where passive proteostasis collapse dominates.
3. Functional Consequence: Optogenetic stimulation of metabolically inefficient but intact neurons in aged mice will fail to evoke network-level responses, proving their functional isolation prior to death.

This reframes age-related neuronal "loss" as a two-stage process: first synaptic eviction, then eventual death. If correct, interventions should differ—boosting metabolic health to prevent silencing in key circuits, while allowing immune clearance of truly senescent precursors.