Abstract
In recent years, a number of groups have been investigating the use of “empty” liposomes with no drug loaded as scavengers both for exogenous intoxicants and endogenous toxic molecules. Preclinical trials have demonstrated that repurposing liposomes to sequester such compounds may prove clinically useful. The use of such “empty” liposomes in the dialysate during dialysis avoids recognition by complement surveillance, allowing high doses of liposomes to be used. The “reach” of dialysis may also be increased to molecules that are not traditionally dialysable. We aim to review the current literature in this area with the aims of increasing awareness and informing further research. A structured literature search identified thirteen papers which met the inclusion criteria. Augmenting the extraction of ammonia in hepatic failure with pH-gradient liposomes with acidic centres in peritoneal dialysis is the most studied area, with work progressing toward phase one trials. Liposomes used to augment the removal of exogenous intoxicants and protein-bound uraemic and hepatic toxins that accumulate in these organ failures and liposome-supported enzymatic dialysis have also been studied. It is conceivable that liposomes will be repurposed from the role of pharmaceutical vectors to gain further indications as clinically useful nanomedical antidotes/treatments within the next decade.
Highlights
Accepted: 13 March 2021Liposomes are spherical particles composed of a phospholipid bilayer encircling an aqueous centre [1]
Improving dialysis of the protein-bound endogenous toxins relating to renal failure with soy phospholipid (SP)-based liposomes, cationic liposomes and liposomes made with linoleic acid was the subject of four studies
One study evaluated liposome-supported enzymatic peritoneal dialysis, and one study evaluated the effects of SP liposomes on dialysis of protein-bound endogenous toxins, which accumulate in hepatic failure
Summary
Accepted: 13 March 2021Liposomes are spherical particles composed of a phospholipid bilayer encircling an aqueous centre [1]. Preclinical trials have demonstrated that repurposing liposomes to sequester such compounds may prove clinically useful [3]. Studies have shown that intravascular “empty” liposomes can sequester compounds in vivo, acting as detoxification vehicles or “sinks” [4]. There are dose limitations to the intravenous (IV) dosing route, as many nanoparticles, including liposomes, can cause complement activation-related pseudoallergy (CARPA) when delivered intravenously [5,6]. This has led to the investigation of the use of liposomes in dialysate
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