Dementia is a major problem of our time. Alzheimer's disease (AD), the leading cause of dementia, accounts for 60-80% of cases, affecting 7 million people in the EU. This number is expected to double over the next 20 years as the population ages. Despite being described by psychiatrist Alois Alzheimer over a century ago, a cure for Alzheimer's disease remains elusive. Finding effective drugs has been a near-impossible task for industry and academic drug discovery, well described by the metaphor of the Death Valley. In June 2021, the FDA approved the antibody aducanumab, the first new AD drug in 18 years, although concerns remain about its efficacy, safety and cost. This highlights the urgent need to continue the development of AD drugs and to meet the challenge by exploring new avenues beyond the current mainstream. The 2017 Nobel Prize in Physiology and Medicine was awarded to Michael Young, Michael Rosbash and Jeffrey Hall “for their discoveries into the molecular mechanisms controlling circadian rhythm”. Disruptions in sleep-wake cycles and circadian rhythms are emerging as early symptoms of AD and correlate with an increased risk of dementia. New research suggests that circadian disruption may play a key role in the onset and progression of AD, making the circadian clock (CC) a promising therapeutic target. Addressing circadian dysfunction could help treat memory and sleep problems at all stages of the disease, from prodromal to preventative stages. TClock4AD has been designed to provide an excellent training platform for a critical rethink of Alzheimer's research and development under the breakthrough idea of targeting CC dysfunction. TClock4AD will provide a double degree to 17 PhD students whose research is structured around 5 scientific themes corresponding to 5 work packages (WPs): (1) develop novel artificial intelligence-, proteolysis targeting chimeras- multitarget and photoswitches-based strategies for identifying drug candidates for CC (2) develop novel drug delivery nanotechnologies, which take into consideration CC (3) investigate innovative in vitro (stem-cells, 3D cultures) & in vivo (Drosophila), as well as organ-on-chip techniques, for preclinical validation of CC drugs (4) get insight into the molecular mechanisms underlying CC in AD and associated drug response in mice and C. elegans models (5) develop an innovative biotech business model and exploitation strategies.