Down the road towards hepatic encephalopathy. Urea synthesis - the liver workhorse of nitrogen metabolism.

Urea synthesis is an irreversible, essential for maintenance of health and life, and highly regulated liver function with a very high capacity for production of the end-product urea-nitrogen. The set-point of urea synthesis in relation to its overall substrate, the prevailing blood concentration of L-α-amino acids, contributes to determine whole-body nitrogen balance and the size and composition of the plasma free amino acid pool. Ammonia is definitively eliminated from the body by urea synthesis.

Down the road towards hepatic encephalopathy. The elusive ammonia- what determines the arterial concentration?

Elevated arterial ammonia is associated with several complications of liver disease as it predicts mortality for in-patients and decompensation, hospitalization and death in out-patients with cirrhosis. In this review, our aim was to estimate how the individual organs contribute to arterial ammonia based on published data from human studies. The brain removes ammonia from arterial blood in a concentration-dependent fashion.

Hyperammonaemic encephalopathy due to non-functioning urea cycle as a complication to gastric bypass surgery.

Hyperammonaemic encephalopathy in the absence of liver failure is a major diagnostic challenge. A rare cause is as a complication to previous gastric bypass surgery, a condition reported to be associated with high mortality. In this case report, we present the exhaustive diagnostic work-up and clinical reversal of deep and recurrent hyperammonaemic encephalopathy in a patient with previous gastric bypass surgery.

Blood ammonia concentration measurement - effects of sampling site and cirrhosis during induced hyperammonaemia.

Background: Ammonia is implicated in hepatic encephalopathy (HE) and prognostic in cirrhosis. Venous ammonia concentration, yielding similar correlation with HE grades as arterial, has become the preferred practise but comparative data are limited.

Aim: To quantify effect of sampling site on ammonia concentration in healthy persons and patients with cirrhosis.

Shotgun DNA sequencing for human identification: Dynamic SNP selection and likelihood ratio calculations accounting for errors.

Shotgun sequencing is a DNA analysis method that potentially determines the nucleotide sequence of every DNA fragment in a sample, unlike PCR-based genotyping methods that is widely used in forensic genetics and targets predefined short tandem repeats (STRs) or predefined single nucleotide polymorphisms (SNPs). Shotgun DNA sequencing is particularly useful for highly degraded low-quality DNA samples, such as ancient samples or those from crime scenes. Here, we developed a statistical model for human identification using shotgun sequencing data and developed formulas for calculating the evidential weight as a likelihood ratio (LR).