Citrinin (CTN) is a mycotoxin produced from Penicillium, Aspergillus, and Monascus fungi. CTN widely and frequently contaminates a variety of grains including corn, wheat, barley, nuts, and spices, leading to global residual levels ranging from 0.08 to 25,000 μg/kg in foods. Notably, the residual levels in Monascus-fermented red yeast rice foods and health supplements can reach 70 to 189,000 μg/kg, with detection rates of 33% to 78%. These observations suggest that CTN may pose potential hazards and risks to human health. CTN is well known for its nephrotoxicity and reproductive toxicity by inducing oxidative stress, mitochondrial damage, apoptosis, chromosomal instability, microtubule disruption, and cell cycle arrest. However, the cardiotoxicity, neurotoxicity, and genotoxicity and carcinogenic characteristics of CTN along with their underlying mechanisms remain unclear. Additionally, an up-to-date health risk assessment for CTN is currently lacking. This study is structured into four sections to address these issues as follows. The first section focuses on the [Cardiotoxic Effects and Mechanisms of CTN]. Based on the critical roles of microtubules and mitochondria in maintaining cardiac morphology and energy supply, it is essential to investigate the potential cardiotoxicity and its underlying mechanisms of CTN. In this study, rat cardiomyoblast H9c2 was used as an in vitro model. The results showed that CTN (25–75 μM) disrupted microtubule cytoskeleton assembly as colchicine did, and the disassembled microtubules thus resulted in mitochondrial misalignment and dysfunction, with those damaged mitochondria accumulated in the cells. Additionally, CTN impaired autophagy in H9c2 cells and triggered the accumulation of lysosomes and ubiquitinated proteins, hindering the clearance of damaged organelles and protein aggregates. Furthermore, CTN (2–50 μM) downregulated the expression of sarcomere genes and interfered the morphology and sarcomere protein expression during and after the H9c2 differentiation. Exposure of CTN (25–50 μM) to an embryonic zebrafish model demonstrated significantly weakened heart contraction and cardiac function indices of the embryonic hearts. Collectively, these data identify and elucidate the in vitro cardiotoxic mechanisms of CTN which involves both microtubules and mitochondria, and CTN-triggered cardiac malfunction was also observed in vivo. The second section includes the [Neurotoxic Effects and Mechanisms of CTN]. Given the essential role of mitochondria in neuronal functioning, this study employed human neuroblastoma cell SH-SY5Y as an in vitro model to assess CTN's neurotoxicity. The transcriptomic profile of CTN (10–20 μM)-treated SH-SY5Y cells revealed downregulation of axon development, neuron projection guidance, and neuron differentiation, as well as upregulation of oxidative stress and electron transport chain. Further experiments confirmed that CTN (2–20 μM) significantly downregulated genes associated with neural differentiation and projection guidance, and inhibited the differentiation and neurite outgrowth of SH-SY5Y cells. Notably, mitochondrial oxidative stress and mitochondrial function were only affected at higher concentration (50 μM), suggesting that neurite outgrowth and differentiation is more sensitive to CTN exposure than mitochondrial dysfunction. These findings present novel evidence of in vitro neurotoxicity of CTN, which expands our fundamental understanding of CTN. The third section explores the [Potential Genotoxicity and Carcinogenic Molecular Characteristics of CTN]. As chromosomal instability is a hallmark of carcinogenesis, this study explored the potential in vitro chromosomal instability and carcinogenic characteristics of CTN by using HEK293 cells that were subjected to either short-term or long-term treatment of CTN, where short-term means 3-day exposure to CTN followed by 27 days of normal culture while long-term denotes continuous 30-day exposure to CTN. The results showed that both short- and long-term treatments (10–20 μM) triggered the formation of abnormal mitotic spindles, a sign of chromosomal instability. RNA sequencing analyses showed enrichment of cell cycle and RTK/KRAS/RAF/MAPK signaling, and the transcriptomic profile closely aligned to various cancer-related gene expression patterns and matched several key molecular characteristics of carcinogenicity. Notably, this genotoxic and carcinogenic potential of CTN was irreversible. These findings provide preliminary evidence for the potential signs of genotoxicity and carcinogenicity of CTN. Finally, this study performed a [Probabilistic Health Risk Assessment of CTN] using a Bayesian-based probabilistic approach. Since high uncertainties existed during the then determination of point of departure for CTN, this study set a new Bayesian-based probabilistic point of departure (45.73 μg/kg bw/day) and human reference dose (0.08 μg/kg bw/day) for CTN with reduced uncertainties. In addition, the probabilistic exposure assessment was conducted using food residual data, food consumption data, and demographic data in Taiwan. The preliminary results showed that up to 40% of the Taiwanese people who frequently consume red yeast rice may face unacceptable risk in a worst-case scenario. However, due to the lack of red yeast rice consumption data, large uncertainties and limitations existed in the exposure assessment of this study so that the risk characterization results cannot be used for recommendations. It is hoped that a more precise risk assessment will be performed in the future to clarify the health risks for Taiwanese people who consume CTN-contaminated red yeast rice. In summary, this study (1) comprehensively elucidates the cardiotoxic effects and mechanisms of CTN which involve the damage of microtubules and mitochondria, the hindered clearance of damaged organelles/proteins, and the impaired cardiac contractile function; (2) identifies for the first time the neurotoxic effects and mechanisms of CTN by demonstrating that neural differentiation and projection guidance are more sensitive to CTN exposure than mitochondrial toxicity and oxidative stress; (3) preliminarily explores the potential genotoxic and carcinogenic characteristics of CTN; and (4) precisely establishes a new probabilistic point of departure and human reference dose for CTN. These findings broaden the foundational understanding of CTN toxicity and offer valuable information for future toxicological studies on citrinin, with the aim of safeguarding public health and welfare.