84 These reductions were independent of serum calcium and phosphate concentrations, and associated with attenuation of both renin mRNA expression in cardiac myocytes and renin, angiotensinogen and renin receptor mRNA
and protein expression in the kidneys.85 Renal fibrosis and inflammation is a process that is driven in part by over activity of the RAS, is ameliorated by standard RAS inhibition (ACE inhibitors (ACEi) or angiotensin receptor blockers), but which can be complicated by renin accumulation which in itself can have deleterious effects.86,87 This is a problem which Tan and colleagues examined with the addition of paricalcitol to a rat model of renal selleck chemical BGB324 manufacturer fibrosis treated with trandalopril.88 In this model, they demonstrated that paricalcitol in combination with an ACEi was effective at suppressing the excess renin production seen with the ACEi alone, and worked additively to reduce renal scar.88 In vivo, there is a paucity of data assessing vitamin D intervention in relation to the RAS system directly. In the controlled case-series by Park et al. they assessed the use of i.v. 1,25-OHD (2 µg twice weekly) for 15 weeks in a HD population, and found that both plasma renin activity and circulating angiotensin
II concentrations were significantly reduced; however, confounding factors such as drug use and the significant suppression of PTH was not controlled for.89 In an elegant translational study by Kong et al. after demonstrating that active vitamin D analogues could successfully MYO10 reduce renin expression both in the kidneys and
heart, with resultant improvements in cardiac mass and function equivalent and additive to the effects of an angiotensin receptor blocker (losartan) in rats, they observed that in as case-series of chronic HD patients the use of an active vitamin D analogue reduced plasma renin activity, which was independent of the reduction in PTH (P < 0.01).90 However, significance was reduced when the use of ARB/ACEI therapy was adjusted for (P = 0.064).90 However, this together with the experimental work of Tan mentioned above highlights the need for prospective trials to be conducted which focus on vitamin D supplements as a specific additive therapy in addition to standard RAS blockade strategies (further explored in Proteinuria section below). Vitamin D’s role in LVH and cardiac function in CKD has only been explored in a small number of studies, looking at predominantly 1,25-OHD administration in haemodialysis (HD) patients with conflicting results.77,89,91–95 Unfortunately, almost all studies have been of relatively short duration (∼3 months), making it difficult to draw firm conclusions about the effect of vitamin D on cardiac function.