Influence of 5-HTTLPR polymorphism on resting state perfusion in patients with major depression

Neuroimaging studies in major depressive disorder (MDD) have indicated dysregulation in a network involving prefrontal cortex, subgenual cingulate and the amygdalae, which is known to be modulated by serotonin. The serotonergic system is the principal target for pharmacological treatment in MDD and the functional variable serotonin promoter polymorphism (5-HTTLPR) influences susceptibility, course and treatment response of MDD. Using data from a previously published sample of 89 MDD-patients, we examined post hoc the effect of 5-HTTLPR status on resting state perfusion, as measured with 99mTc-HMPAO-SPECT. MDD patients were stratified according to receptor polymorphism, both using a bi-allelic (group A: L/L vs. group B: S/S and S/L genotype) and a tri-allelic approach (Group A′: LA/LA vs. Group B′: non-LA/LA genotype). There were no significant differences between both subgroups regarding age, gender, severity of depression, medication, or treatment response (p \u3e 0.1). Using the bi-allelic approach, Group B, compared to group A, revealed a significantly higher resting state perfusion in medial prefrontal cortex (pvoxel (FWE) \u3c 0.05). Additional ROI analyses showed relative overactivity of the amygdalae in group B (pvoxel (FWE) \u3c 0.05). Similar effects were observed in the tri-allelic approach. The opposite contrasts (Group A \u3e Group B) revealed no significant effects. We demonstrate that in patients with MDD, 5-HTTLPR gene polymorphism modulates resting state perfusion in key structures of mood processing. While the clinical impact of these findings will need to be further investigated in larger cohort studies, the necessity to monitor and to account for individual 5-HTTLPR-status in future MDD imaging studies is highly recommended

HER2-directed antibodies, affibodies and nanobodies as drug-delivery vehicles in breast cancer with a specific focus on radioimmunotherapy and radioimmunoimaging

Purpose The aim of the present paper is to review the role of HER2 antibodies, affibodies and nanobodies as vehicles for imaging and therapy approaches in breast cancer, including a detailed look at recent clinical data from antibody drug conjugates and nanobodies as well as affibodies that are currently under development. Results Clinical and preclinical studies have shown that the use of monoclonal antibodies in molecular imaging is impaired by slow blood clearance, associated with slow and low tumor uptake and with limited tumor penetration potential. Antibody fragments, such as nanobodies, on the other hand, can be radiolabelled with short-lived radioisotopes and provide high-contrast images within a few hours after injection, allowing early diagnosis and reduced radiation exposure of patients. Even in therapy, the small radioactively labeled nanobodies prove to be superior to radioactively labeled monoclonal antibodies due to their higher specificity and their ability to penetrate the tumor. Conclusion While monoclonal antibodies are well established drug delivery vehicles, the current literature on molecular imaging supports the notion that antibody fragments, such as affibodies or nanobodies, might be superior in this approach