Underprescription of medications in older adults: causes, consequences and solutions-a narrative review.

PURPOSE: Under-prescription is defined as the omission of a medication that is indicated for the treatment of a condition or a disease, without any valid reason for not prescribing it. The aim of this review is to provide an updated overview of under-prescription, summarizing the available evidence concerning its prevalence, causes, consequences and potential interventions to reduce it. METHODS: A PubMed search was performed, using the following keywords: under-prescription; under-treatment; prescribing omission; older adults; polypharmacy; cardiovascular drugs; osteoporosis; anticoagulant. The list of articles was evaluated by two authors who selected the most relevant of them. The reference lists of retrieved articles were screened for additional pertinent studies. RESULTS: Although several pharmacological therapies are safe and effective in older patients, under-prescription remains widespread in the older population, with a prevalence ranging from 22 to 70%. Several drugs are underused, including cardiovascular, oral anticoagulant and anti-osteoporotic drugs. Many factors are associated with under-prescription, e.g. multi-morbidity, polypharmacy, dementia, frailty, risk of adverse drug events, absence of specific clinical trials in older patients and economic factors. Under-prescription is associated with negative consequences, such as higher risk of cardiovascular events, worsening disability, hospitalization and death. The implementation of explicit criteria for under-prescription, the use of the comprehensive geriatric assessment by geriatricians, and the involvement of a clinical pharmacist seem to be promising options to reduce under-prescription. CONCLUSION: Under-prescription remains widespread in the older population. Further studies should be performed, to provide a better comprehension of this phenomenon and to confirm the efficacy of corrective interventions.

A bioartificial kidney device with polarized secretion of immune modulators.

The accumulation of protein-bound toxins in dialyzed patients is strongly associated with their high morbidity and mortality. The bioartificial kidney device (BAK), containing proximal tubule epithelial cells (PTECs) seeded on functionalized synthetic hollow fibre membranes, may be a powerful solution for the active removal of those metabolites. In an earlier study, we developed an upscaled BAK containing conditionally immortalized human PTEC with functional organic cationic transporter 2. Here, we first extended this development to a BAK device having cells with the organic anionic transporter 1, capable of removing anionic uraemic wastes. We confirmed the quality of the conditionally immortalized human PTEC monolayer by confocal microscopy and paracellular inulin-fluorescein isothiocyanate leakage, as well as by the active transport of anionic toxin, indoxyl sulphate. Furthermore, we assessed the immune safety of our system by measuring the production of relevant cytokines by the cells after lipopolysaccharide stimulation. Upon lipopolysaccharide treatment, we observed a polarized secretion of proinflammatory cytokines by the cells: 10-fold higher in the extraluminal space, corresponding to the urine compartment, as compared with the intraluminal space, corresponding to the blood compartment. To the best of our knowledge, our work is the first to show this favourable cell polarization in a BAK upscaled device.

Bioengineered kidney tubules efficiently excrete uremic toxins.

The development of a biotechnological platform for the removal of waste products (e.g. uremic toxins), often bound to proteins in plasma, is a prerequisite to improve current treatment modalities for patients suffering from end stage renal disease (ESRD). Here, we present a newly designed bioengineered renal tubule capable of active uremic toxin secretion through the concerted action of essential renal transporters, viz. organic anion transporter-1 (OAT1), breast cancer resistance protein (BCRP) and multidrug resistance protein-4 (MRP4). Three-dimensional cell monolayer formation of human conditionally immortalized proximal tubule epithelial cells (ciPTEC) on biofunctionalized hollow fibers with maintained barrier function was demonstrated. Using a tailor made flow system, the secretory clearance of human serum albumin-bound uremic toxins, indoxyl sulfate and kynurenic acid, as well as albumin reabsorption across the renal tubule was confirmed. These functional bioengineered renal tubules are promising entities in renal replacement therapies and regenerative medicine, as well as in drug development programs.

Human proximal tubule epithelial cells cultured on hollow fibers: living membranes that actively transport organic cations.

The bioartificial kidney (BAK) aims at improving dialysis by developing 'living membranes' for cells-aided removal of uremic metabolites. Here, unique human conditionally immortalized proximal tubule epithelial cell (ciPTEC) monolayers were cultured on biofunctionalized MicroPES (polyethersulfone) hollow fiber membranes (HFM) and functionally tested using microfluidics. Tight monolayer formation was demonstrated by abundant zonula occludens-1 (ZO-1) protein expression along the tight junctions of matured ciPTEC on HFM. A clear barrier function of the monolayer was confirmed by limited diffusion of FITC-inulin. The activity of the organic cation transporter 2 (OCT2) in ciPTEC was evaluated in real-time using a perfusion system by confocal microscopy using 4-(4-(dimethylamino)styryl)-N-methylpyridinium iodide (ASP(+)) as a fluorescent substrate. Initial ASP(+) uptake was inhibited by a cationic uremic metabolites mixture and by the histamine H2-receptor antagonist, cimetidine. In conclusion, a 'living membrane' of renal epithelial cells on MicroPES HFM with demonstrated active organic cation transport was successfully established as a first step in BAK engineering.

Biotechnological challenges of bioartificial kidney engineering.

With the world-wide increase of patients with renal failure, the development of functional renal replacement therapies have gained significant interest and novel technologies are rapidly evolving. Currently used renal replacement therapies insufficiently remove accumulating waste products, resulting in the uremic syndrome. A more preferred treatment option is kidney transplantation, but the shortage of donor organs and the increasing number of patients waiting for a transplant warrant the development of novel technologies. The bioartificial kidney (BAK) is such promising biotechnological approach to replace essential renal functions together with the active secretion of waste products. The development of the BAK requires a multidisciplinary approach and evolves at the intersection of regenerative medicine and renal replacement therapy. Here we provide a concise review embracing a compact historical overview of bioartificial kidney development and highlighting the current state-of-the-art, including implementation of living-membranes and the relevance of extracellular matrices. We focus further on the choice of relevant renal epithelial cell lines versus the use of stem cells and co-cultures that need to be implemented in a suitable device. Moreover, the future of the BAK in regenerative nephrology is discussed.