Pharmacokinetics of intravenous ATP in cancer patients.

OBJECTIVE: To characterise the pharmacokinetics of adenosine 5'-triphosphate (ATP) in patients with lung cancer after i.v. administration of different ATP dosages. METHODS: Twenty-eight patients received a total of 176 i.v. ATP courses of 30 h. Fifty-two infusions were given as low-dose infusions of 25-40 microg kg(-1) min(-1), 47 as middle-dose infusions of 45-60 microg kg(-1) min(-1) and 77 as high-dose infusions of 65-75 microg kg(-1) min(-1) ATP. Kinetic data of ATP concentrations in erythrocytes were available from 124 ATP courses. Results are expressed as mean +/- SEM. RESULTS: Most ATP courses in cancer patients were without side effects (64%), and side effects occurring in the remaining courses were mild and transient, resolving within minutes after decreasing the infusion rate. Baseline ATP concentration in erythrocytes was 1,554 +/- 51 micromol l(-1). ATP plateau levels at 24 h were significantly increased by 53 +/- 3, 56 +/- 3 and 69 +/- 2% after low-dose, middle-dose and high-dose ATP infusions, respectively. At the same time, significant increases in plasma uric acid concentrations were observed: 0.06 +/- 0.01, 0.11 +/- 0.01 and 0.16 +/- 0.01 mmol l(-1), respectively. The mean half-time for disappearance of ATP from erythrocytes, measured in five patients, was 5.9 +/- 0.5 h. CONCLUSIONS: During constant i.v. infusion of ATP in lung cancer patients, ATP is taken up by erythrocytes and reaches dose-dependent plateau levels 50-70% above basal concentrations at approximately 24 h.

Effects of ATP infusion on glucose turnover and gluconeogenesis in patients with advanced non-small-cell lung cancer.

Cancer cachexia is associated with elevated lipolysis, proteolysis and gluconeogenesis. ATP infusion has been found to significantly inhibit loss of body weight, fat mass and fat-free mass in patients with advanced lung cancer. The present study was aimed at exploring the effects of ATP on whole-body glucose turnover, alanine turnover and gluconeogenesis from alanine. Twelve patients with advanced non-small-cell lung cancer (NSCLC) were studied 1 week before and during 22-24 h of continuous ATP infusion. After an overnight fast, turnover rates of glucose and alanine, and gluconeogenesis from alanine, were determined using primed constant infusions of ¿6, 6-(2)H(2)glucose and ¿3-(13)Calanine. Thirteen NSCLC patients and eleven healthy subjects were studied as control groups without ATP infusion. During high-dose ATP infusion (75 microg.min(-1).kg(-1)), glucose turnover was 0.62+/-0.07 mmol.h(-1).kg(-1), compared with 0. 44+/-0.13 mmol.h(-1).kg(-1) at baseline (P=0.04). For gluconeogenesis a similar, but non-significant, trend was observed ¿baseline, 0.30+/-0.16 mmol.h(-1).kg(-1); during ATP, 0.37+/-0.13 mmol.h(-1).kg(-1) (P=0.08). At lower ATP doses (37-50 microg. min(-1).kg(-1)) these effects were not detected. The relative increase in glucose turnover during ATP infusion compared with baseline showed a significant correlation with the ATP dose (r=0.58, P=0.02). No change in alanine turnover was observed at any ATP dose. The results of this study indicate an increase in glucose turnover during high-dose ATP infusion compared with baseline levels. During high-dose ATP infusion, glucose turnover was similar to that during low-dose ATP infusion and to that in control NSCLC patients. Between ATP infusions, however, glucose turnover in patients treated with high-dose ATP was significantly lower than that in the low-dose and control NSCLC patients (P=0.04 and P=0.03 respectively), and similar to that in healthy subjects. This would suggest that repeated high-dose ATP infusions may inhibit glucose turnover between infusion periods.

Randomized clinical trial of adenosine 5'-triphosphate in patients with advanced non-small-cell lung cancer.

BACKGROUND: Extracellular adenosine 5'-triphosphate (ATP) is involved in the regulation of a variety of biologic processes, including neurotransmission, muscle contraction, and liver glucose metabolism, via purinergic receptors. In nonrandomized studies involving patients with different tumor types including non-small-cell lung cancer (NSCLC), ATP infusion appeared to inhibit loss of weight and deterioration of quality of life (QOL) and performance status. We conducted a randomized clinical trial to evaluate the effects of ATP in patients with advanced NSCLC (stage IIIB or IV). METHODS: Fifty-eight patients were randomly assigned to receive either 10 intravenous 30-hour ATP infusions, with the infusions given at 2- to 4-week intervals, or no ATP. Outcome parameters were assessed every 4 weeks until 28 weeks. Between-group differences were tested for statistical significance by use of repeated-measures analysis, and reported P values are two-sided. RESULTS: Twenty-eight patients were allocated to receive ATP treatment and 30 received no ATP. Mean weight changes per 4-week period were -1.0 kg (95% confidence interval [CI] = -1.5 to -0.5) in the control group and 0.2 kg (95% CI = -0.2 to +0.6) in the ATP group (P =.002). Serum albumin concentration declined by -1.2 g/L (95% CI= -2.0 to -0.4) per 4 weeks in the control group but remained stable (0.0 g/L; 95% CI = -0.3 to +0.3) in the ATP group (P =.006). Elbow flexor muscle strength declined by -5.5% (95% CI = -9.6% to -1. 4%) per 4 weeks in the control group but remained stable (0.0%; 95% CI= -1.4% to +1.4%) in the ATP group (P =.01). A similar pattern was observed for knee extensor muscles (P =.02). The effects of ATP on body weight, muscle strength, and albumin concentration were especially marked in cachectic patients (P =.0002, P =.0001, and P =. 0001, respectively, for ATP versus no ATP). QOL score changes per 4-week period in the ATP group showed overall less deterioration than in the control group-physical scores (-0.2% versus -2.4%; P =. 0002); functional scores (+0.4% versus -5.5%; P =.02); psychologic scores (-0.7% versus -2.4%; P =.11); overall QOL score (+0.1% versus -3.5%; P =.0001). CONCLUSIONS: This randomized trial demonstrates that ATP has beneficial effects on weight, muscle strength, and QOL in patients with advanced NSCLC.

Adenosine triphosphate: established and potential clinical applications.

Adenosine 5'-triphosphate (ATP) is a purine nucleotide found in every cell of the human body. In addition to its well established role in cellular metabolism, extracellular ATP and its breakdown product adenosine, exert pronounced effects in a variety of biological processes including neurotransmission, muscle contraction, cardiac function, platelet function, vasodilatation and liver glycogen metabolism. These effects are mediated by both P1 and P2 receptors. A cascade of ectonucleotidases plays a role in the effective regulation of these processes and may also have a protective function by keeping extracellular ATP and adenosine levels within physiological limits. In recent years several clinical applications of ATP and adenosine have been reported. In anaesthesia, low dose adenosine reduced neuropathic pain, hyperalgesia and ischaemic pain to a similar degree as morphine or ketamine. Postoperative opioid use was reduced. During surgery, ATP and adenosine have been used to induce hypotension. In patients with haemorrhagic shock, increased survival was observed after ATP treatment. In cardiology, ATP has been shown to be a well tolerated and effective pulmonary vasodilator in patients with pulmonary hypertension. Bolus injections of ATP and adenosine are useful in the diagnosis and treatment of paroxysmal supraventricular tachycardias. Adenosine also allowed highly accurate diagnosis of coronary artery disease. In pulmonology, nucleotides in combination with a sodium channel blocker improved mucociliary clearance from the airways to near normal in patients with cystic fibrosis. In oncology, there are indications that ATP may inhibit weight loss and tumour growth in patients with advanced lung cancer. There are also indications of potentiating effects of cytostatics and protective effects against radiation tissue damage. Further controlled clinical trials are warranted to determine the full beneficial potential of ATP, adenosine and uridine 5'-triphosphate.

The effect of nitric oxide donors on haemodynamics and blood flow distribution in the porcine carotid circulation.

1. The role of nitric (NO) in the regulation of capillary and arteriovenous anastomotic blood flow was evaluated in the carotid circulation of the pig. For this purpose, the effect of intracarotid (i.c.) infusions of saline and two NO donors, nitroprusside sodium (NPR) and S-nitroso-N-acetylpenicillamine (SNAP) in concentrations of 3-100 micrograms min-1 was studied on systemic haemodynamics and carotid blood flow and its distribution in anaesthetized pigs with low arteriovenous anastomotic blood flow, by use of the radioactive microsphere method. 2. Apart from heart rate, which increased after both NPR and SNAP, no major changes in systemic haemodynamic variables were observed. In contrast to saline, both NPR and SNAP increased common carotid blood flow, vascular conductance and vascular pulsations dose-dependently. 3. The distribution of the carotid artery blood flow over capillary and arteriovenous anastomotic fraction remained stable after saline infusions. Both NPR and SNAP enhanced total capillary blood flow and conductance. In contrast to NPR, arteriovenous anastomotic blood flow and conductance were increased by SNAP. 4. At the tissue level, capillary blood flow increases following NPR or SNAP were reflected by an increase in both extracerebral and dural blood flow without changes in total brain blood flow. 5. These results indicate that both NO donors cause arteriolar dilatation together with enhanced vascular pulsations in the carotid circulation of the pig. Probably by way of a 'steal' phenomenon, this pronounced arteriolar dilatation limits the effect of NO donors on arteriovenous anastomoses. 6. The results of the present investigation support the contention that dilatation of intra- and extra cranial arteries and arteriovenous anastomoses leads to increased vascular pulsations, which (rather than increased blood flow) could, at least in part, be responsible for the headache caused by nitro vasodilators.