Solitary fibrous tumor of the retropharynx causing obstructive sleep apnea.

Solitary fibrous tumors (SFTs) are rare, usually benign, spindle cell neoplasms that most often originate near mesothelium-lined surfaces of the pleural or peritoneal cavity. SFTs reported in the head and neck occur most commonly in the oral cavity, sinonasal tract, and orbit. We report a case of SFT of the retropharynx causing severe obstructive sleep apnea. The diagnostic and management strategies of SFTs are discussed.

The murine platelet and plasma factor V pools are biosynthetically distinct and sufficient for minimal hemostasis.

Coagulation factor V (FV) is a central regulator of the coagulation cascade. Circulating FV is found in plasma and within platelet alpha granules. The specific functions of these distinct FV pools are uncertain. We now report the generation of transgenic mice with FV gene expression restricted to either the liver or megakaryocyte/platelet lineage using bacterial artificial chromosome (BAC) constructs. Six of 6 independent albumin BAC transgenes rescue the neonatal lethal hemorrhage of FV deficiency. Rescued mice all exhibit liver-specific Fv expression at levels ranging from 6% to 46% of the endogenous Fv gene, with no detectable FV activity within the platelet pool. One of the 3 Pf4 BAC transgenes available for analysis also rescues the lethal FV null phenotype, with FV activity restricted to only the platelet pool (approximately 3% of the wild-type FV level). FV-null mice rescued by either the albumin or Pf4 BAC exhibit nearly normal tail bleeding times. These results demonstrate that Fv expression in either the platelet or plasma FV pool is sufficient for basal hemostasis. In addition, these findings indicate that the murine platelet and plasma FV pools are biosynthetically distinct, in contrast to a previous report demonstrating a plasma origin for platelet FV in humans.

Biosynthetic origin and functional significance of murine platelet factor V.

Factor V (FV), a central regulatory protein in hemostasis, is distributed into distinct plasma and platelet compartments. Although platelet FV is highly concentrated within the platelet alpha-granule, previous analysis of human bone marrow and liver transplant recipients has demonstrated that platelet FV in these individuals originates entirely from the uptake of plasma FV. In order to examine further the biosynthetic origins of the platelet and plasma FV pools, we performed bone marrow transplantations of Fv-null (Fv-/-) fetal liver cells (FLCs) into wild-type mice. Fractionation of whole blood from control mice demonstrated that approximately 14% of total blood FV activity is platelet-associated. Mice that received transplants of Fv-null FLCs displayed a high degree of engraftment and appeared grossly normal, with no evidence for spontaneous hemorrhage. Although total FV levels in Fv-null FLC recipients were only mildly decreased, the FV activity within the platelet compartment was reduced to less than 1% of that in normal mice. We conclude that the murine platelet FV compartment is derived exclusively from primary biosynthesis within cells of marrow origin, presumably megakaryocytes, and that an intact platelet FV pool is not required for protection from spontaneous hemorrhage or bleeding following minor trauma.