In mice, the hormone alpha‑melanocyte‑stimulating hormone (the basis of melanotan‑I) can blunt inflammation‑driven fever, blood‑cell spikes, and some immune protein changes caused by the inflammatory signals IL‑1 and TNF. The effect works both when the peptide is given under the skin and when tiny amounts are injected directly into the brain, showing a link between the nervous system and immune response. However, the study used mouse models and direct injections, not the ways people would normally take melanotan‑I, so the findings aren’t ready to be turned into a home protocol.

Administration of the pituitary hormone alpha-melanocyte-stimulating hormone (alpha-MSH) to mice was found to inhibit a number of IL-1 and TNF-inducible biologic responses in situ. The ability of either IL-1 or TNF to cause fever, enhance plasma levels of acute phase proteins, and increase the numbers of peripheral blood neutrophils was inhibited by the simultaneous peripheral administration of this neuropeptide. In addition, alpha-MSH reversed the depressive influences of IL-1 or TNF on the effector phase of contact hypersensitivity (CH) responses in animals given an adoptive transfer of primed lymphocytes from hapten-sensitized donors. Intracerebral injection of nanogram quantities of alpha-MSH inhibited the ability of peripherally administered IL-1 or TNF to induce both fever and neutrophilia without affecting the increase in plasma levels of serum amyloid P and fibrinogen. Also, nanogram quantities of alpha-MSH given intracerebrally to normal mice did not reverse the depressed CH responses observed after peripheral IL-1 or TNF administration. These findings suggest that both fever and neutrophilia are linked to the direct action of IL-1 or TNF on the brain. This was supported by the observation that an intracerebral injection of IL-1 or TNF in low doses increased core body temperature and circulating neutrophil numbers without affecting plasma levels of acute phase proteins or CH responsiveness. Our results provide additional support for the hypothesis that bidirectional control exists between elements of the neuroendocrine and immune systems.