Fraction of exhaled nitric oxide is higher in liver transplant recipients than in controls from the general population: a cohort study.

Background: Fraction of exhaled nitric oxide with an expiratory flow of 50 mL/s (FENO50) is a biomarker of eosinophilic airway inflammation. Liver transplant recipients have an increased risk of pulmonary infections, but little is known about the burden of chronic pulmonary diseases in this group. We aimed to assess the prevalence of elevated FENO50 in liver transplant recipients and compare it to controls from the general population. Methods: FENO50 was measured in 271 liver transplant recipients from The Danish Comorbidity in Liver Transplant Recipients (DACOLT) study and 1,018 age- and sex-matched controls from The Copenhagen General Population Study (CGPS). Elevated FENO50 was defined as ≥25 or ≥50 parts per billion (ppb). The analyses were adjusted for known and suspected confounders. Results: The median age of the liver transplant recipients was 55 years (interquartile range (IQR) 46-64), and 58% were men. The liver transplant recipients had a higher median FENO50 than the controls [16 ppb (IQR 10-26) vs. 13 ppb (IQR 8-18.), p < 0.001]. Furthermore, the liver transplant recipients had a higher prevalence of elevated FENO50 (for FENO50 ≥25 ppb 27% vs. 11%, p < 0.001 and ≥50 ppb 4% vs. 2%, p = 0.02). The results were similar after adjusting for age, sex, smoking status, use of airway medication, and blood eosinophil counts [the adjusted odds ratio (OR) for FENO50 ≥25 ppb was 3.58 (95% CI: 2.50-5.15, p < 0.0001) and the adjusted OR for FENO50 ≥50 ppb was 3.14 (95% CI: 1.37-7.20, p = 0.007)]. Conclusion: The liver transplant recipients had elevated FENO50, implying increased eosinophilic airway inflammation. The clinical impact of this finding needs further investigation.

Resting myocardial dysfunction in cirrhosis quantified by tissue Doppler imaging.

BACKGROUND: Cirrhotic cardiomyopathy is described as latent cardiac failure. However, it remains to be investigated whether the myocardial dysfunction is present even at rest. AIMS: The aim of the present study was to quantify left ventricular function at rest by means of tissue Doppler imaging in patients with cirrhosis and relate the findings to liver status and cirrhosis aetiology. METHODS: Forty-four consecutive patients and 23 age-matched healthy controls were included. Conventional echocardiographic- and tissue Doppler-derived indices of systolic and diastolic function were obtained. Liver function was quantified by the galactose elimination capacity and clinical stage by the Child-Pugh and MELD scores. RESULTS: Both systolic and diastolic myocardial functions were compromised in the patients at rest. Left ventricular ejection fraction (56.4 ± 6.1 vs. 59.9 ± 3.9%, P<0.02), mean peak systolic tissue velocity (4.6 ± 0.9 vs. 5.6 ± 0.7 cm/s, P<0.001) and mean systolic strain rate (-1.23 ± 0.19 vs. -1.5 ± 0.14/s, P<0.001) were all reduced in cirrhosis patients. Thirty-four patients (54%) had diastolic dysfunction, 11 had impaired diastolic relaxation pattern (25%), 12 had the more severe pseudonormal filling pattern (27%) and one had restrictive filling or severe diastolic dysfunction (2%). None of the echocardiographic findings were related to the cirrhosis aetiology. CONCLUSION: Tissue Doppler imaging during rest detected substantial systolic and diastolic myocardial dysfunction in cirrhotic patients. This supports the existence of a distinct cirrhotic cardiomyopathy.

IL-6 has no acute effect on the regulation of urea synthesis in vivo in rats.

BACKGROUND: Clinical or experimentally induced, active inflammation up-regulates the in vivo capacity of urea synthesis (CUNS), which promotes nitrogen removal from the body and metabolic catabolism. We have shown that tumor necrosis factor α (TNF-α) up-regulates CUNS and increases interleukin 6 expression (IL-6) within hours of administration. The described effect of TNF-α on nitrogen homeostasis may, therefore, depend on IL-6. METHODS: Three hours after the i.v. injection of 125 µg.kg⁻¹ of IL-6 or placebo, we evaluated the CUNS, hepatocyte urea cycle enzyme protein levels and the mRNA levels of the urea cycle enzyme genes in rats. The prevailing rat serum acute phase proteins and their liver mRNA levels were also measured. RESULTS: IL-6 did not change CUNS or hepatocyte urea cycle enzyme protein levels, whereas urea cycle enzyme mRNA levels, except for ornithine transcarbamylase (OTC), decreased by approximately 20%. The liver mRNA levels of α2MG, haptoglobin and α1AGP all increased by 1.5- to 2-fold (p < 0.001). In serum, only the α2MG concentration slightly increased (p < 0.001), whereas the levels of the other circulating acute phase proteins remained unchanged. CONCLUSION: IL-6 is not the mediator of the in vivo CUNS up-regulation observed 3 h after TNF-α administration, but it may be involved in the down-regulation of urea cycle genes. IL-6 may also mediate TNF-α effects on acute phase protein gene expression. Thus, IL-6 did not contribute to the in vivo hepatic component of inflammation-associated catabolism.

Unchanged capacity of urea synthesis during acute phase response in rats.

BACKGROUND: The acute phase response presents a catabolic event related to increased waste of amino-N via hepatic urea synthesis despite an increased need for amino-N incorporation into acute phase proteins. In our previous studies, tumour necrosis factor-α (TNF-α) acutely up-regulated the in vivo capacity of urea-nitrogen synthesis (CUNS) in rats before the hepatic acute phase response was established. To extend these observations, this study aimed to clarify the regulation of N elimination via urea during the later stages of the acute phase response. METHODS: Twenty-four hours after i.v. injection of 25 µg kg(-1) TNF-α or placebo, we determined the in vivo CUNS, hepatocyte urea cycle enzyme protein levels and mRNA levels of the urea cycle enzyme genes in pair-fed rats. In addition, serum acute phase proteins and their liver mRNA levels were measured. RESULTS: After TNF-α, CUNS and hepatocyte urea cycle enzyme protein expressions were unchanged while urea cycle enzyme mRNA levels decreased. Liver mRNA levels of α2MG, haptoglobin and α1AGP rose and their serum levels increased equally. CONCLUSION: Despite a fully established 24-h acute phase response, there was no change in the in vivo capacity for disposal of amino-N by urea synthesis or in the urea cycle enzyme proteins, although the expression of the urea cycle enzyme genes was decreased. Thus, in vivo urea synthesis was not orchestrated together with acute phase protein synthesis so as to limit N waste despite genetic regulation to this effect. This may contribute towards catabolism of inflammation.

Tumor necrosis factor-alpha acutely up-regulates urea synthesis in vivo in rats--a hepatic component of inflammatory catabolism?

BACKGROUND: Catabolism is a serious problem in patients with active inflammation. The tissue nitrogen (N) depletion is related to increased hepatic capacity for elimination of N via conversion of amino-N into urea-N. This is caused by the inflammatory process, but the mediators responsible are unknown. Tumor necrosis factor-alpha (TNF-alpha) plays a key role in inflammation, and we hypothesized that TNF-alpha up-regulates urea synthesis. METHODS: We examined the in vivo capacity of urea-N synthesis (CUNS) and mRNA levels of urea cycle enzyme genes 3 h after TNF-alpha injection in rats. Circulating concentrations of glucagon, corticosterone, insulin, glucose, cytokines and acute phase proteins and their liver tissue gene expressions were measured. RESULTS: TNF-alpha increased CUNS by 40% (p=0.03) despite decreased urea-cycle enzyme gene expression. TNF-alpha increased interleukin 6 (IL-6) (p < 0.001); circulating acute phase proteins were unchanged. CONCLUSION: TNF-alpha in rats caused an acute up-regulation of the in vivo capacity of urea synthesis which may promote loss of nitrogen from the body and catabolism. The results indicate that TNF-alpha has a post-transcriptional effect on regulation of urea synthesis that is independent of the acute phase protein synthesis. Effects of IL-6 may be involved.