Bilirubin- and light induced cell death in a murine lymphoma cell line.

Cells from the mouse lymphoma cell line L5178Y-R were exposed to blue light from phototherapy lamps in the presence of solutions of 160 microM bilirubin supplemented with serum albumin. HPLC analysis showed that the bilirubin solution was photooxidised as a function of increasing light dose. The cells were stained with trypan blue to score necrosis, and apoptosis was assayed by the terminal deoxynucleotide transferase assay (TdT) or by studying the nuclear structure in cells stained with propidium iodide. A rapidly developing apoptosis was observed after light doses killing 60-80% of the cells as judged from the trypan blue exclusion test. The fraction of apoptotic cells was smaller than the fraction of necrotic cells. Exposure of the cells to fractions of light at a high dose rate was compared to the effect of the same total dose at a lower dose rate given as a single fraction. No large differences were found, however, there was a tendency of a higher degree of necrosis as well as apoptosis in the cells receiving the light in fractions at a high dose rate.

Cerebral blood flow autoregulation after moderate hypoxemia in the newborn piglet.

The isotope-labelled microsphere method was used to study blood flow autoregulation in the brainstem (BS), cerebellum (CBL), cerebrum (CBR) and choroid plexus (ChPl) in 21 newborn piglets exposed to hypoxemia and/or hypovolemia. One group of piglets (n = 7) was made hypoxemic by breathing 10% O2 for 10 min, a second group (n = 8) was studied during hypoxemia (10% O2, 10 min), followed by hypovolemia (bleeding 20% of estimated blood volume). A third group of piglets (n = 6) was made hypovolemic by bleeding 20%. Hypoxemia significantly impaired the autoregulatory capacity in CBL and CBR resulting in a pressure-passive flow pattern. Hypovolemia alone did not produce any significant cerebral vascular response in BS, CBL and CBR, not even when hypovolemia was preceded by hypoxemia, indicating a rapid restoration of the autoregulatory capacity of the cerebral vasculature after hypoxemia of moderate duration. The hypotension seen both during hypoxemia and hypovolemia was gradually compensated for and normalized within 60 min. However, animals exposed to both hypoxemia and hypovolemia were still hypotensive 60 min after the hypoxemic insult. Cardiac output (CO) was not affected by hypoxemia, but was consistently reduced in hypovolemia. We therefore speculate that in the newborn a reduced CO might be a more specific parameter for hypovolemia than a low blood pressure.

Effect of nimodipine on cerebral and organ blood flow in normal and posthypoxemic newborn piglets.

Using the isotope-labelled microsphere method, blood flow to the brain, the heart and the kidneys were studied in newborn piglets during nimodipine infusion. Twenty piglets were studied in two different groups. Group 1 (n = 8) was kept normoxic and given a continuous nimodipine infusion (15 micrograms/kg/min). Group 2 (n = 12) was made hypoxemic by breathing 10% O2 for 10 min followed by an identical nimodipine infusion as group 1. In spite of a significant systemic hypotension, nimodipine infusion alone significantly increased blood flow in the brain stem and right cardiac ventricle at 30-60 min of infusion, while blood flow to cerebellum, cerebrum and the left cardiac ventricle did not change. Blood flow to the kidneys decreased significantly. In posthypoxemic piglets nimodipine infusion gave almost similar flow patterns, however, the changes appeared at an earlier time. We conclude that in spite of a significant reduction in blood pressure, cerebral and cardiac blood flow is preserved both in normal and posthypoxemic animals even at high doses of nimodipine. However, because of the decreased blood flow to the kidneys further dose-response studies are needed before clinical use in asphyctic newborns.