The paper explains that the thymus gland makes hormones like thymosin‑alpha‑1 that not only help the immune system but also affect brain and hormone signals. As we age, the thymus shrinks, which may weaken these signals and contribute to the overall decline in body balance.

The thymic-pituitary axis constitutes a bidirectional circuit where the ascending feedback loop is effected by thymic factors of epithelial origin. The aim of the present article is, first, to introduce the idea of an immune-neuroendocrine homeostatic network in higher animals. Next, the relevance of the thymus in this network and the possible role of this gland in the neuroendocrine imbalances associated with aging are discussed. A number of studies are next reviewed which show that the endocrine thymus produces several bioactive molecules, generally called thymic hormones, which in addition to possessing immunoregulatory properties are also active on nervous and endocrine circuits. In particular, the reported activities of thymosin fraction five, thymosin alpha 1 and thymosin beta 4 on beta-endorphin, adrenocorticotropic hormone, glucocorticoids, luteinizing hormone-releasing hormone and luteinizing hormone secretion in different animal and cell models are reviewed. The known hypophysiotropic actions of other thymic hormones like thymulin, homeostatic thymus hormone and thymus factor are also summarized, and the impact of aging on pituitary responsiveness to thymic hormones is discussed. As a conclusion, it is proposed that in addition to its central role in the regulation of the immune function, the thymus gland may extend its influence to nonimmunologic components of the body, including the neuroendocrine system. The early onset of thymus involution might, therefore, act as a triggering event which would initiate the gradual decline in homeostatic potential that characterizes the aging process.