Abstract
Animal data indicate that melatonin secretion is stimulated by the paraventricular nucleus (PVN) of the hypothalamus and that lesions of the PVN mimic the endocrine effects of pinealectomy. Since the PVN lies adjacent to the third ventricle, I propose that periventricular damage, which is found in schizophrenia and may account for the third ventricular dilatation seen on computed tomographic (CT), may disrupt PVN-pineal interactions and ultimately enhance the process of pineal calcification (PC). To investigate this hypothesis, I conducted CT study on the relationship of PC size to third ventricular width (TVW) in 12 chronic schizophrenic patients (mean age: 33.7 years; SD = 7.3). For comparison, I also studied the relationship of PC size to the ventricular brain ratio and prefrontal cortical atrophy. As predicted, there was a significant correlation between PC size and TVW (r pbi =. 61, p <. 05), whereas PC was unrelated to the control neuroradiological measures. The findings support the hypothesis that periventricular damage may be involved in the process of PC in schizophrenia and may indirectly implicate damage to the PVN in the mechanisms underlying dysfunction of the pineal gland in schizophrenia. In a second study, I investigated the prevalence of habenular calcification (HAC) on CT in a cohort of 23 chronic schizophrenic-patients (mean age: 31.2 years; SD = 5.95). In this sample HAC was present in 20 patients (87%). Since the prevalence of HAC in a control population of similar age is only 15% these data reveal an almost 6-fold higher prevalence of HAC (X2 = 84.01, p <. 0001) in chronic schizophrenia as compared to normal controls. The implications of HAC for the pathophysiology of schizophrenia are discussed in light of the central role of the habenula in the regulation of limbic functions.