Plasma fibronectin levels during cardiopulmonary bypass

Plasma fibronectin, also called cold-insoluble globulin, is a cryoprecipitable glycoprotein with both opsonic and adhesive activities. It binds to collagen, actin, and heparin and can form soluble as well as cryoprecipitable complexes in the cold. Fibronectin augments particulate phagocytosis by the reticuloendothelial system and can influence lung vascular permeability. Plasma fibronectin deficiency is temporally associated with respiratory failure in septic surgical, trauma, and burn patients. We measured plasma fibronectin and albumin levels in nine adults undergoing elective cardiopulmonary bypass to determine whether dilution alone could account for the changes in plasma fibronectin. Plasma fibronectin concentration decreased 17% with the surgical trauma of opening of the chest and placement of the vascular cannulas. On heparinization and initiation of cardiopulmonary bypass, plasma fibronectin fell an additional 48% (P less than 0.001), whereas albumin concentration (corrected for albumin in the pump prime) fell only 25% (P less than 0.001), emphasizing that dilution was not the only mechanism contributing to the decline in plasma fibronectin. Fibronectin levels began to increase after discontinuation of cardiopulmonary bypass and in association with diuresis, but unexpectedly they remained subnormal until 4 days postoperation. Thus the decline in fibronectin concentration with cardiopulmonary bypass may be due to dilution as well as opsonic consumption and possible complexing with heparin in the cold.

Studies on the interaction between GP-18-0-deficient neutrophils and vascular endothelium

A patient whose neutrophils lack the glycoprotein gp-180 shows an increased susceptibility to bacterial infections. Neutrophils from this patient migrate abnormally both in vivo and in vitro. To examine the basis for this abnormality in migration, a study was carried out on the interaction of gp-180-deficient neutrophils with artificial surfaces and with human endothelial cell cultures. Compared with normal neutrophils. gp-180-deficient neutrophils showed decreased adhesion to cold-insoluble globulin-coated plastic surfaces, and their ability to spread on this substratum was greatly impaired. In contrast, gp-180- deficient neutrophils interacted in a normal fashion with endothelial monolayers, attaching to their surfaces and migrating between cell junctions to spread between the monolayers and the subjacent plastic. A normal interaction with endothelium in vivo was implied by the finding that the rise in the neutrophil count in response to epinephrine, an index of the marginated pool, was normal in the gp-180-deficient patient. We conclude that the abnormal function of gp-180-deficient cells is unlikely to be caused by a faulty interaction with the vascular endothelium. We postulate instead that these cells migrate poorly in vivo because of an abnormal interaction with extravascular connective tissue matrix constituents.

Studies on the interaction between GP-18-0-deficient neutrophils and vascular endothelium

A patient whose neutrophils lack the glycoprotein gp-180 shows an increased susceptibility to bacterial infections. Neutrophils from this patient migrate abnormally both in vivo and in vitro. To examine the basis for this abnormality in migration, a study was carried out on the interaction of gp-180-deficient neutrophils with artificial surfaces and with human endothelial cell cultures. Compared with normal neutrophils. gp-180-deficient neutrophils showed decreased adhesion to cold-insoluble globulin-coated plastic surfaces, and their ability to spread on this substratum was greatly impaired. In contrast, gp-180- deficient neutrophils interacted in a normal fashion with endothelial monolayers, attaching to their surfaces and migrating between cell junctions to spread between the monolayers and the subjacent plastic. A normal interaction with endothelium in vivo was implied by the finding that the rise in the neutrophil count in response to epinephrine, an index of the marginated pool, was normal in the gp-180-deficient patient. We conclude that the abnormal function of gp-180-deficient cells is unlikely to be caused by a faulty interaction with the vascular endothelium. We postulate instead that these cells migrate poorly in vivo because of an abnormal interaction with extravascular connective tissue matrix constituents.