Inherited coagulation disorders are caused by a large number of genetic abnormalities. However, the determination of the clinical impact for some of these genetic variations is challenging for the molecular biologist.In a first part, we characterized large genomic rearrangements in haemophilia patients using cytogentic microarray analysis. In a first study, we delineated six F9 complete deletions in order to investigate genotype/phenotype correlations. We identified SOX3 as a candidate gene for intellectual disability (ID) found Haemophilia B patients. In a second study, we described five complex Xq28 rearrangements in Haemophilia A (HA) patients. We showed that several F8 neighbouring genes are involved in these rearrangements and some of these genes are involved in other pathologies such as ID, physical abnormalities and cardiovascular disease. Such investigations would be particularly useful for genetic counseling in female carriers to assess the risk of transmitting haemophilia associated with other diseases.In a second, we developed a minigene assay to characterise putative splice site mutations in F8 and we showed that 21 out of the 26 variations studied are associated with splicing defect.In the third part, we described two original molecular mechanisms leading to coagulation disorders. In a first case, we reported a recurrent deep intronic deletion in mild HA. We gave some evidences that this deletion promoted AluY exonization in F8 transcrits. Due to its high prevalence (6.1%), this deletion must be investigated in all patients with mild HA in whom no mutation has been detected by standard genetic analysis. In the second study we investigated the mechanism responsible for bleeding tendency in patient carrying the THBD c.1611C>A and having high levels of soluble thrombomoduline (TM). We showed that a higher sensitivity of the mutated TM to the proteolysis by metalloproteases and a defect of TM synthesis seemed responsible for TM shedding