Establishing generalized verb-noun instruction-following skills in retarded children

Diazotized (125I)-diiodosulfanilic acid (DD125ISA) binds specifically to the exposed proteins on the surface of the rabbit platelet plasma membrane. This was demonstrated by the following observations with the use of sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) of whole platelets and the isolated plasma membrane fraction: (1) the specific activity of isolated membrane protein was sevenfold that of whole platelet protein, (2) no proteins of intact platelets were labeled which were not represented in the isolated plasma membrane, (3) DD125ISA-labeled proteins were altered by trypsin treatment of intact, labeled platelets, and (4) the pattern of labeling produced by reaction of isolated membranes with DD125ISA differed from that produced by the labeling of intact platelets. Reaction of DD125ISA with intact platelets produced labeling of only the three membrane glycoproteins (molecular weights: 180,000, 125,000, and 92,000 daltons) with greatest labeling of the largest glycoprotein and least labeling of the smallest glycoprotein. When rabbit platelets were labeled simultaneously with DD125ISA and 51Cr, the two isotopes were similarly distributed in various density populations of platelets. Some DD125ISA was solubilized from labeled and washed platelets by sonication, but all platelet DD125ISA was recovered in the plasma membrane fraction after 30 minutes' circulation in vivo. In vivo 51Cr recovery and survival were not altered by simultaneous labeling of platelets with DD125ISA. The disappearance of DD125ISA from circulating platelets (T 1/2 = 17 hours) was more rapid than 51Cr (T 1/2 = 30 hours) and appeared exponential in contrast to the linear 51Cr disappearance. On the other hand, DD125ISA did not disappear from platelets faster than 51Cr when doubly labeled platelets were harvested after 3 hours' circulation and incubated in autologous plasma (T 1/2 of DD125ISA elution = 43 hours, 51Cr = 33 hours). SDS-PAGE analysis of DD125ISA-labeled platelets after 14 to 20 hours' circulation in vivo demonstrated the same pattern of DD125ISA distribution on membrane glycoproteins as on the platelets prior to infusion. We interpret this symmetrical loss of the membrane label to indicate symmetrical loss of membrane proteins, suggesting that the platelet may lose pieces of membrane and not specific surface proteins during circulation. This could occur during reversible adhesion encounters during the process of hemostasis and cause the smaller size and decreased effectiveness of older platelets.     

An infrared study of the carbon monoxide complexes of cytochrome P-450 and cytochrome P-420

The infrared stretch vibrations (upsilonCO) of the CO-complexes of cytochrome P-450 and cytochrome P-420 have been determined from infrared difference spectra. The CO-complexes exhibit IR-bands at 1949 cm-1 and 1966 cm-1 with half widths of approximately 17 cm-1 and approximately 20 cm-1 respectively. These results are compared with the CO-stretch frequencies of other haemoproteins and discussed with respect to specific interactions of the CO-ligand with the protein moiety and to the ligand trans to CO of the cytochromes.     

Hypernatremia--problems in management

Hypernatremia may be produced under several different circumstances but most frequently is the result of excessive water loss with diarrhea and the excessive solute load secondary to inappropriate preparation of formula. The clinical manifestations vary and depend primarily on the degree of dehydration and the rate at which the hyperosmolar state has been reached. The management of the patient will, of course, depend upon the mechanism of hypernatremia and degree of dehydration and/or hypovolemia that is present. It seems clear that the exact nature of the rehydrating solution is not of major importance. The volume is of great concern but most vital seems to be the rate of rehydration. If rehydration is accomplished too rapidly the child becomes edematous, develops increased intracranial pressure, stupor, and convulsions. If fluids are given slowly and at a well regulated rate, these complications can usually be avoided. The patient should be monitored regularly with electrolytes, careful determination of weights, and records of intake and output. The rate of rehydration should be monitored to assure that the planned schedule of 24 to 72 hours (depending on the severity of the problem) is followed. Approximately 10 to 15 per cent of children with serum sodium of 160 mEq per liter or greater will have permanent neurological deficits.