Hidden Complexity of Pediatric Platelet Disorders: Functional Diversity and Unexpected Hypercoagulable Phenotypes

Pediatric platelet disorders are commonly classified according to specific structural or functional abnormalities, yet it remains unclear how well these diagnoses capture overall hemostatic phenotype. Here, we combined quantitative single-cell platelet measurements with spatially resolved plasma clotting analysis to characterize pediatric patients with dense granule deficiency, platelet function defects, immune thrombocytopenia, and other inherited platelet disorders. Quantitative fluorescence microscopy revealed reduced dense granule abundance not only in dense granule deficiency but also in several patients from other diagnostic groups. Measurements of platelet adhesion, spreading, and calcium signaling identified substantial functional diversity, with individual patients exhibiting distinct combinations of abnormalities that were not predicted by diagnostic category. Unexpectedly, plasma clotting analysis frequently revealed hypercoagulable behavior, including accelerated fibrin clot growth and spontaneous fibrin formation, despite clinical diagnoses associated with platelet-related bleeding disorders. Hypercoagulable phenotypes occurred across multiple diagnostic groups and did not show a simple relationship with platelet functional abnormalities. Together, these findings reveal previously unrecognized complexity in pediatric platelet disorders and suggest that platelet and plasma pathways contribute independently to hemostatic variability. These findings argue that pediatric platelet disorders are best viewed as multidimensional functional phenotypes rather than isolated platelet defects and motivate broader integration of platelet and coagulation measurements in future studies.