Influence of red cell water content on the morphology of sickling

The response of sickle cells with varying water content to alterations in oxygen tension has been studied. Cells that were severely dehydrated while sickled retained the characteristic sickled morphology even after prolonged reoxygenation. When the cell water content was increased by reduction of the suspending medium osmolality, the cells unsickled. Cells that were dehydrated before deoxygenation were unable to assume the spiculated morphology typical of sicked cells. This was true both for high mean cell hemoglobin concentration (MCHC) discoid sickle cells and for irreversibly sickled cells. When such cells were resuspended in hypotonic medium before deoxygenation, they sickled with the characteristic morphology of sickle cells with normal MCHC. The morphological behavior of Ca-loaded sickled cells as well as irreversibly sickled cells showed a major influence of increased hemoglobin concentration and extremely high internal viscosity. Constraint on cell morphology by putative membrane rigidity was not observed.</jats:p

Influence of red cell water content on the morphology of sickling

Abstract The response of sickle cells with varying water content to alterations in oxygen tension has been studied. Cells that were severely dehydrated while sickled retained the characteristic sickled morphology even after prolonged reoxygenation. When the cell water content was increased by reduction of the suspending medium osmolality, the cells unsickled. Cells that were dehydrated before deoxygenation were unable to assume the spiculated morphology typical of sicked cells. This was true both for high mean cell hemoglobin concentration (MCHC) discoid sickle cells and for irreversibly sickled cells. When such cells were resuspended in hypotonic medium before deoxygenation, they sickled with the characteristic morphology of sickle cells with normal MCHC. The morphological behavior of Ca-loaded sickled cells as well as irreversibly sickled cells showed a major influence of increased hemoglobin concentration and extremely high internal viscosity. Constraint on cell morphology by putative membrane rigidity was not observed.</jats:p

Rapid DNA detection by beacon-assisted detection amplification

This protocol describes a new and rapid isothermal reaction process designed to amplify and detect a specific DNA sequence in purified DNA extracted from cultured cells. The protocol uses a DNA nanomachine that comprises two molecular switches that function in concert to isothermally amplify and detect a DNA target. First, a molecular beacon detection switch is 'activated' only if a DNA target sequence is present. A DNA primer and DNA polymerase are used to lock the beacon in an activated conformation. Second, an amplification and signal-transduction switch is initiated following successful activation. A nicking endonuclease and the DNA polymerase are used to replicate the DNA target. Both switches operate simultaneously at 40 °C in a single reaction to rapidly generate multiple copies of the DNA target in a cyclic polymerization reaction. This protocol enables femtomole amounts of a DNA target to be reproducibly amplified and detected i