Improving the clearance of protein-bound uremic toxins using cationic liposomes as an adsorbent in dialysate

Computer-aided design of short peptide ligands targeting N-formyl peptide MT-ND6: potential application in treating severe inflammatory diseases

High levels of N-formyl peptide MT-ND6 in serum are significantly associated with disease severity and mortality in critically ill patients, including those with sepsis and severe acute pancreatitis. Selective removal of MT-ND6 in blood to reduce inflammation and tissue damage may be an important immunomodulatory strategy. In the present study, we designed peptide ligands that could bind to MT-ND6 with high affinity. Molecular docking, MD, and MM-PBSA were used to investigate the affinity and stability of peptide/MT-ND6 complexes. To examine the usefulness of affinity ligands for MT-ND6, three peptides were fixed on polystyrene-divinylbenzene (PS) microspheres and adsorption capacity was studied. Adsorption tests showed the adsorbent PS-RF had the higher adsorption percentage (85.42 ± 1.74%) for MT-ND6 than PS microspheres (44.42 ± 2.73%). Moreover, the maximum adsorption capacity of PS-RF reached 6042.96 pg g-1. PS-based immunosorbents loaded with different peptides have no hemolytic effect, no significant effect on blood cell composition and blood coagulation activity, and no cytotoxicity, indicating good biocompatibility. In conclusion, the ligand RF screened by computer-aided molecular design exhibits a stronger affinity to MT-ND6 and it can significantly enhance the adsorption efficiency of MT-ND6 in serum. The PS-RF immunosorbent has great potential for the removal of MT-ND6 by hemoperfusion. The screening process of peptide ligands also provides a basis for the further design and optimization of affinity ligands for MT-ND6.

Injectable Nano-Micron AKBA Delivery Platform for Treatment of Tendinopathy in a Rat Model

Tendinopathy is a disorder characterized by pain and reduced function due to a series of changes in injured or diseased tendons. Inflammation and collagen degeneration are key contributors to the onset and chronic nature of tendinopathy. Acetyl-11-keto-β-boswellic acid (AKBA) is an effective anti-inflammatory agent widely used in chronic inflammatory disorders and holds potential for tendinopathy treatment; however, its therapeutic efficacy is limited by poor aqueous solubility. Here, we fabricated AKBA-encapsulated cationic liposome-gelatin methacrylamide (GelMA) microspheres (GM-Lipo-AKBA) using thin-film hydration and microfluidic technology for drug delivery therapy. GM-Lipo-AKBA exhibited high encapsulation efficiency, extended AKBA release for over 4 weeks, and prolonged degradation. In vitro and in vivo experiments demonstrated its effectiveness in improving inflammation and ECM remodeling in tendinopathy. In summary, the injectable nano-micron drug delivery platform provides a promising strategy for the sustained and localized delivery of AKBA for tendinopathy treatment.

Clearance of Protein-Bound Uremic Toxins Using Anion Nanotraps with Record High Uptake

Traditional hemodialysis often fails to remove protein-bound uremic toxins (PBUTs) like p-cresyl sulfate (pCS) and indoxyl sulfate (IS) due to their strong binding to human serum albumin, which is linked to adverse cardiovascular outcomes. Herein, a class of cationic polymeric networks, denoted as CPN-X6-CPN-X9, are reported for the efficient removal of PBUTs. The abundant imidazole-based nanotraps in these cationic polymeric networks confer a highly positive charge density, resulting in CPN-X7 achieving a maximum sorption capacity of 1000.8 mg/g for pCS and CPN-X6 offering a maximum sorption capacity of 1028.4 mg/g for IS, surpassing all previously reported sorbents. Furthermore, CPN-X9, which is relatively hydrophobic, exhibits remarkable selectivity in competitive experiments involving large amount of chloride ions and serum albumin, attaining removal rates of up to 74% for pCS and 93% for IS in the recycling in vitro dialysis mode. Meanwhile, CPN-X9 demonstrates excellent recyclability over five cycles, and the cationic polymeric network materials exhibit satisfactory hemocompatibility. The sorption mechanism of the anion exchange process is fully elucidated and verified by density functional theory (DFT) calculations. This study provides valuable insights into enhancing the removal efficiency of PBUTs and presents broad prospects in the field of clinical blood purification.

Liposome-siderophore conjugates loaded with moxifloxacin serve as a model for drug delivery against Mycobacterium tuberculosis

Tuberculosis (TB) is an infectious disease that annually affects millions of people, and resistance to available antibiotics has exacerbated this situation. Another notable characteristic of Mycobacterium tuberculosis, the primary causative agent of TB, is its ability to survive inside macrophages, a key component of the immune system. In our quest for an effective and safe treatment that facilitates the targeted delivery of antibiotics to the site of infection, we have proposed a nanotechnology approach based on an iron chelator. Iron chelators are the primary mechanism by which bacteria acquire iron, a metal essential for their metabolism. Four liposomes were synthesized and characterized using the dynamic light scattering technique (DLS), nanoparticle tracking analysis (NTA), and transmission electron microscopy (TEM). All of these methods revealed the presence of spherical particles, approximately 200 nm in size. NTA indicated a concentration of around 1011 particles/mL. We also developed and validated a high-performance liquid chromatography method for quantifying Moxifloxacin to determine encapsulation efficiency (EE) and release profiles (RF). The EE was 51.31 % for LipMox and 45.76 % for LipIchMox. Scanning electron microscopy (SEM) and transmission electron microscopy (TEM) confirmed the phagocytosis of liposomal vesicles by macrophages. Functionalizing liposomes with iron chelators can offer significant benefits for TB treatment, such as targeted drug delivery to intracellular bacilli through the phagocytosis of liposomal particles by cells like macrophages.

Derivation and elimination of uremic toxins from kidney-gut axis

Uremic toxins are chemicals, organic or inorganic, that accumulate in the body fluids of individuals with acute or chronic kidney disease and impaired renal function. More than 130 uremic solutions are included in the most comprehensive reviews to date by the European Uremic Toxins Work Group, and novel investigations are ongoing to increase this number. Although approaches to remove uremic toxins have emerged, recalcitrant toxins that injure the human body remain a difficult problem. Herein, we review the derivation and elimination of uremic toxins, outline kidney-gut axis function and relative toxin removal methods, and elucidate promising approaches to effectively remove toxins.

Uremic toxins in chronic kidney disease highlight a fundamental gap in understanding their detrimental effects on cardiac electrophysiology and arrhythmogenesis

Chronic kidney disease (CKD) and cardiovascular disease (CVD) have an estimated 700-800 and 523 million cases worldwide, respectively, with CVD being the leading cause of death in CKD patients. The pathophysiological interplay between the heart and kidneys is defined as the cardiorenal syndrome (CRS), in which worsening of kidney function is represented by increased plasma concentrations of uremic toxins (UTs), culminating in dialysis patients. As there is a high incidence of CVD in CKD patients, accompanied by arrhythmias and sudden cardiac death, knowledge on electrophysiological remodeling would be instrumental for understanding the CRS. While the interplay between both organs is clearly of importance in CRS, the involvement of UTs in pro-arrhythmic remodeling is only poorly investigated, especially regarding the mechanistic background. Currently, the clinical approach against potential arrhythmic events is mainly restricted to symptom treatment, stressing the need for fundamental research on UT in relation to electrophysiology. This review addresses the existing knowledge of UTs and cardiac electrophysiology, and the experimental research gap between fundamental research and clinical research of the CRS. Clinically, mainly absorbents like ibuprofen and AST-120 are studied, which show limited safe and efficient usability. Experimental research shows disturbances in cardiac electrical activation and conduction after inducing CKD or exposure to UTs, but are scarcely present or focus solely on already well-investigated UTs. Based on UTs data derived from CKD patient cohort studies, a clinically relevant overview of physiological and pathological UTs concentrations is created. Using this, future experimental research is stimulated to involve electrophysiologically translatable animals, such as rabbits, or in vitro engineered heart tissues.

pH Gradient Liposomes Extract Protein Bound Amitriptyline in Peritoneal Dialysis-Exploratory Work

Poisoning is a significant cause of injury-related death worldwide. Dialysis is usually ineffective in removing the toxin once it has been absorbed because of drug protein binding and high volumes of distribution. In this work, we explore whether the addition of liposomes to peritoneal dialysate could extract protein bound amitriptyline. Liposomes were prepared using the thin film hydration method. In the in vitro experiment, 3 mL of 20% albumin with a concentration of 6000 nmol/L amitriptyline in a proprietary dialysis cartridge was dialysed against 125 mL of phosphate-buffered saline with and without 80 mg 1,2-dioleoyl-sn-glycero-3-phosphoglycerol (DOPG) liposomes. In the in vivo arm, peritoneal dialysis was undertaken in 6 rats with pH gradient liposome augmented dialysate after intravenous amitriptyline injection. Peritoneal blood flow was estimated by CO₂ extraction. Total amitriptyline extracted was compared to freely dissolved (non-protein bound) and total amitriptyline perfusing the membrane during the peritoneal dwell. Mean liposome size for DOPG and acidic centre pH gradient liposomes was 119 nm and 430 nm, respectively. In the in vitro experiment, more amitriptyline was extracted into the liposome containing dialysate than the control dialysate (40 +/- 2 nmol/L vs. 27 +/- 1 nmol/L). In the in vivo experiment, the total amitriptyline in dialysate was 5240 +/- 2750 nmol. Mean total free amitriptyline perfusing the peritoneal membrane was 93 +/- 46 nmol. Mean total blood amitriptyline perfusing the peritoneal membrane was 23,920 +/- 6920 nmol. Two of the six animals were excluded due to overestimation of peritoneal blood flow. This exploratory work suggests the addition of liposome nanoparticles to peritoneal dialysate extracted protein bound amitriptyline from blood.

Polyethyleneimine-anchored liposomes as scavengers for improving the efficiency of protein-bound uremic toxin clearance during dialysis

Protein-bound uremic toxins (PBUTs) are significant toxins that are closely related to the prognosis of chronic kidney disease. They cannot be effectively removed by conventional dialysis therapies due to their high albumin binding affinity. Our previous research revealed that cationic liposomes (i.e., polyethyleneimine [PEI]-decorated liposomes) could enhance the clearance of PBUTs via electrostatic interactions. However, the poor biocompatibility (hemolysis) restricted their applications in clinical dialysis treatment. Herein, we produced PEI-anchored, linoleic acid-decorated liposomes (CP-LA liposomes) via the conjugation of PEI to cholesterol chloroformate (Chol-PEI, CP), and linoleic acid (LA) was added to provide liposomal colloidal stability. The CP-LA liposomes outperformed the plain liposomes, demonstrating significantly higher PBUT binding rates and removal rates. In addition, in vitro dialysis simulation verified that the CP-LA liposomes had a better capacity for PBUT clearance than the plain liposomes, especially for PBUTs with a strong negative net charge. Hemolysis and cytotoxicity tests revealed that the biocompatibility of the CP-LA liposomes was better than that of the physically-decorated PEI-liposome. CP-LA liposomes possess great potential for PBUT clearance in clinical dialysis therapy.

Liposomes to Augment Dialysis in Preclinical Models: A Structured Review

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.