Docosahexaenoic acid (DHA) is indispensable for neurological health, yet its therapeutic potential is hampered by poor bioavailability and non-specific brain distribution. We hypothesized that co-admi Show more
Docosahexaenoic acid (DHA) is indispensable for neurological health, yet its therapeutic potential is hampered by poor bioavailability and non-specific brain distribution. We hypothesized that co-administering DHA with specific molecular carriers - eicosapentaenoic acid (EPA) or phosphatidylserine (PS) - would exploit distinct cellular transport pathways to achieve region-specific brain enrichment and associated neuroprotection. By dietary intervention using C57BL/6J mice, we employed regional lipidomics, ELISA, and western blotting to assess brain fatty acid incorporation, neurotrophic factor levels, inflammatory signaling, and transporter expression following supplementation with DHA alone or in combination with EPA or PS. Lipidomic analyses revealed striking, carrier-dependent spatial modulation of DHA. Co-administration with EPA enriched the cortex and striatum, while PS co-administration preferentially targeted the hippocampus and cortex. Mechanistically, both carrier-DHA complexes enhanced the expression of the key blood-brain barrier (BBB) transporter MFSD2A. Functionally, this precision delivery activated distinct neuroprotective programs. PS + DHA robustly upregulated the CREB-BDNF neurotrophic pathway, while EPA + DHA uniquely suppressed the NF-κB pathway, demonstrating potent anti-inflammatory effects. These results demonstrate that the choice of molecular carrier dictates both the spatial distribution of DHA and the nature of the ensuing neuroprotective response. Our findings establish that dietary co-supplementation with specific lipid carriers enables precise spatial delivery of DHA by engaging specific transporters, thereby activating distinct neuroprotective programs in a region-specific manner. This work provides a mechanistic framework for a precision nutrition strategy, tailoring DHA formulations to target specific neuroanatomical and cellular vulnerabilities in neurological disorders. Show less