Temperature-induced ultradense PEG polyelectrolyte surface grafting provides effective long-term bioresistance against mammalian cells, serum, and whole blood.

We report a facile method of generating ultradense poly(l-lysine)-graft-poly(ethylene glycol) (PLL-g-PEG) surface by using high temperature alone, which in turn provides dramatic improvement in resisting nonspecific bioadsorption. X-ray photoelectron spectroscopy (XPS) revealed that the surface graft density increased ~4 times higher on the surface prepared at 80 °C compared to 20 °C. The studies from small-angle X-ray scattering (SAXS) and the effect of varying ionic strength during/post assemblies at 20 and 80 °C indicated that the "cloud point grafting effect" is not the cause for obtaining high density grafting. Stringent long-term bioresistance tests have been conducted and the temperature-induced PLL-g-PEG surfaces have achieved (1) zero mammalian cell adsorption/migration for up to 36 days and (2) extremely close-to-zero protein adsorptions have been observed even after 36 days in 10% serum media and 24 h in whole blood within the ultrasensitive detection limit of time-of-flight secondary ion mass spectrometry (ToF-SIMS).

Accelerated blood clearance was not induced for a gadolinium-containing PEG-poly(L-lysine)-based polymeric micelle in mice.

PURPOSE: Accelerated blood clearance (ABC) is induced by repeated injections of PEGylated liposomes. In this study, the ABC was investigated for a gadolinium-containing PEG-poly(L-lysine)-based polymeric micelle (Gd-micelle) and PEGylated liposome (Gd-liposome) in mice. MATERIALS AND METHODS: Effects of the first injection of Gd-micelle on the tissue distribution of the second dose of Gd-micelle were studied. Additionally, effects of the first injection of Gd-micelle, Gd-liposome, empty liposome, polyethyleneglycol (PEG(500,000)), and PEG-lipid on the distribution of the second dose of the Gd-liposome were evaluated. RESULTS: Results indicated that the tissue distribution of the second injection of the Gd-micelle at a dose of 33, 5, or 2 micromol Gd/kg was not affected by the first injection of the Gd-micelle at different doses and time intervals or of the empty PEGylated liposome 7 days before. ABC of Gd-liposome at a dose of 2.3 micromol Gd/kg (corresponding to 10 micromol lipids/kg) was observed when the empty PEGylated liposome or Gd-liposome, but not the Gd-micelle, PEG(500,000) or PEG-lipid, was pre-administered. CONCLUSIONS: The hydrophobic core of the micelle or lipid bilayer of PEGylated liposome has a major effect on this phenomenon. These studies have significant implications for the evaluation of PEG-poly(L-lysine)-based micellar formulation of Gd-based contrast agents.

PEGylation of polylysine dendrimers improves absorption and lymphatic targeting following SC administration in rats.

Polylysine dendrimers have potential as highly flexible, biodegradable nanoparticular carriers that may also promote lymphatic transport. The current study was undertaken to determine the impact of PEGylation on the absorption and lymphatic transport of polylysine dendrimers modified by surface derivatisation with PEG (200, 570 or 2000Da) or 4-benzene sulphonate following SC or IV dosing. PEGylation led to the PEG(200) derived dendrimer being rapidly and completely absorbed into the blood after SC administration, however only 3% of the administered dose was recovered in pooled thoracic lymph over 30h. Increasing the PEG chain length led to a systematic decrease in absorption into the blood and an enhancement of the proportion recovered in the lymphatics (up to 29% over 30h). For the PEG(570) and PEG(2000) derived dendrimers, indirect access to the lymph via equilibration across the capillary beds also appeared to play a role in lymphatic targeting after both IV and SC dosing. In contrast, the anionic benzene sulphonate-capped dendrimer was not well absorbed from the SC injection site (26% bioavailability) into either the blood or the lymph. The data suggest that PEGylated poly-L-lysine dendrimers are well absorbed from SC injection sites and that the extent of lymphatic transport may be enhanced by increasing the size of the PEGylated dendrimer complex.

Preparation and in vivo imaging of PEG-poly(L-lysine)-based polymeric micelle MRI contrast agents.

A polymeric micelle drug carrier system was applied to the targeting of an MRI (magnetic resonance imaging) contrast agent. A block copolymer, PEG-b-poly(L-lysine), was used for conjugation of gadolinium ions through chelating moieties, DOTA. The DOTA moieties were successfully conjugated to all primary amine groups of the lysine residues. The obtained block copolymer, PEG-b-poly(L-lysine-DOTA), formed a polymeric micelle. The polymeric micelle structure was maintained even after partial gadolinium chelation ( approximately 40%) to the DOTA moieties. The prepared polymeric micelle MRI contrast agent was injected into a mouse tail vein at a dose of 0.05 mmol Gd/kg. The polymeric micelle-based MRI contrast agent exhibited stable blood circulation. A considerable amount (6.1+/-0.3% of ID/g of the polymeric micelle) was found to accumulate at solid tumors 24 h after intravenous injection by means of the EPR effect. An MRI analysis revealed that the signal intensity of the tumor was enhanced 2.0-fold by the use of this contrast agent.

Partly-PEGylated Poly-L-lysine dendrimers have reduced plasma stability and circulation times compared with fully PEGylated dendrimers.

The current study was performed to examine the effect of 50% surface PEGylation on the plasma circulation, biodistribution and metabolism of intravenously administered Generation 4 poly-L-lysine dendrimers in rats. Partial surface PEGylation blocked the rapid and extensive vascular binding previously described for the non-PEGylated dendrimer and slowed metabolism of the core, however the effect was less than that observed for total surface coverage of PEG. Capping the residual surface amines with acetyl groups further improved plasma stability.

The impact of molecular weight and PEG chain length on the systemic pharmacokinetics of PEGylated poly l-lysine dendrimers.

The impact of PEGylation on the pharmacokinetics and biodistribution of (3)H-labeled poly l-lysine dendrimers has been investigated after intravenous administration to rats. The volumes of distribution, clearance and consequently the plasma half-lives of the PEGylated dendrimers were markedly dependent on the total molecular weight of the PEGylated dendrimer, but were not specifically affected by the PEG chain length alone. In general, the larger dendrimer constructs (i.e. >30 kDa) had reduced volumes of distribution, were poorly renally cleared and exhibited extended elimination half-lives ( t 1/2 1-3 days) when compared to the smaller dendrimers (i.e. <20 kDa) which were rapidly cleared from the plasma principally into the urine ( t 1/2 1-10 h). At later time points the larger dendrimers concentrated in the organs of the reticuloendothelial system (liver and spleen); however, the absolute extent of accumulation was low. Size exclusion chromatography of plasma and urine samples revealed that the PEGylated dendrimers were considerably more resistant to biodegradation in vivo than the underivatized poly l-lysine dendrimer cores. The results suggest that the size of PEGylated poly l-lysine dendrimer complexes can be manipulated to optimally dictate their pharmacokinetics, biodegradation and bioresorption behavior.

Cationic poly-L-lysine dendrimers: pharmacokinetics, biodistribution, and evidence for metabolism and bioresorption after intravenous administration to rats.

Cationic poly-L-lysine 3H-dendrimers with either 16 or 32 surface amine groups (BHALys [Lys]4 [3H-Lys]8 [NH2]16 and BHALys [Lys]8 [3H-Lys]16 [NH2]32, generation 3 and 4, respectively) have been synthesized and their pharmacokinetics and biodistribution investigated after intravenous administration to rats. The species in plasma with which radiolabel was associated was also investigated by size exclusion chromatography (SEC). Rapid initial removal of radiolabel from plasma was evident for both dendrimers (t(1/2) < 5 min). Approximately 1 h postdose, however, radiolabel reappeared in plasma in the form of free lysine and larger (but nondendrimer) species that coeluted with albumin by SEC. Plasma and whole blood pharmacokinetics were similar, precluding interaction with blood components as a causative factor in either the rapid removal or reappearance of radioactivity in plasma. Administration of monomeric 3H L-lysine also resulted in the appearance in plasma of a radiolabeled macromolecular species that coeluted with albumin by SEC, suggesting that biodegradation of the dendrimer to L-lysine and subsequent bioresorption may explain the pharmacokinetic profiles. Capping the Lys8 dendrimer with D-lysine to form BHALys [Lys]4 [3H-Lys]8 [D-Lys]16 [NH2]32 resulted in similar, and very rapid, initial disappearance kinetics from plasma when compared to the L-lysine capped dendrimer. Since significant extravasation of these large hydrophilic molecules seems unlikely, this most likely reflects both elimination and extensive binding to vascular surfaces. Capping with "non-natural" D-lysine also appeared to render the dendrimer essentially inert to the biodegradation process. For the L-lysine capped dendrimers, radiolabel was widely distributed throughout the major organs, with no apparent selectivity for organs of the reticuloendothelial system. In contrast, a greater proportion of the administered radiolabel was recovered in the organs of the reticuloendothelial system for the D-lysine capped system, as might be expected for a nondegrading circulating foreign colloid. To our knowledge this is the first data to demonstrate the biodegradation/bioresorption of poly-L-lysine dendrimers and has significant implications for the utility of these systems as drugs or drug delivery systems.

Efficiency of polymer beads in the removal of heparin: toward the development of a novel reactor.

Administration of heparin during extracorporeal procedures increases the risk of haemorrhage. Various reactor designs, including the use of heparinase and poly-L-lysine. HBr hollow fiber, have been investigated for the removal of heparin prior to the blood being returned to the patient; however, none of them have been implemented clinically. In this paper it is proposed that beads made from poly-L-lysine/alginate can be used to remove the heparin. The aim of this work is to perform the necessary experiments in order to get the information required to design a heparin removal reactor that uses these beads. The experiments are aimed at measuring the removal rates of heparin by the beads, testing the efficiency of the beads to remove heparin, determining repeatability and identifying factors that could influence the removal rate. Batch rate experiments using poly-L-lysine/alginate beads in saline solutions were performed to investigate the removal rate of heparin. The results, which indicate that heparin is efficiently removed, may lead to improved bioreactor designs.

Systemic circulation of poly(L-lysine)/DNA vectors is influenced by polycation molecular weight and type of DNA: differential circulation in mice and rats and the implications for human gene therapy.

Effective gene therapy for diseases of the circulation requires vectors capable of systemic delivery. The molecular weight of poly(L-lysine) (pLL) has a significant effect on the circulation of pLL/DNA complexes in mice, with pLL(211)/DNA complexes displaying up to 20 times greater levels in the blood after 30 minutes compared with pLL(20)/DNA. It is shown that pLL(20)/DNA complexes fix mouse complement C3 in vitro, independent of immunoglobulin binding; are less soluble in the blood in vivo; bind erythrocytes; are rapidly removed by the liver, where they associate predominantly with Kupffer cells; and result in a rapid increase in hepatic leukocytes expressing high levels of complement receptor 3 (CR3). The circulation properties of these complexes are also dependent on the type of DNA used, with circular plasmid DNA complexes exhibiting increased circulation compared with linear DNA. PLL(211)/DNA complexes bind erythrocytes and associate with Kupffer cells but, in contrast, do not fix mouse complement in vitro and are unaffected by the type of DNA used. In rats, both types of complexes produce hematuria and are rapidly removed from the circulation. Correlation of in vivo and in vitro results suggests that the solubility of complexes in physiological saline and species-matched complement fixation and erythrocyte lysis may correlate with systemic circulation. Analysis using human blood in vitro shows no hemolysis, but both types of complexes fix complement and bind IgG, suggesting that pLL/DNA complexes may be rapidly cleared from the human circulation.

Enhanced liver blood concentrations of adenine arabinoside accomplished by lactosaminated poly-L-lysine coupling: implications for regional chemotherapy of hepatic micrometastases.

Conjugates of antiviral and antiblastic nucleoside analogs (NAs) with galactosyl-terminating peptides selectively enter hepatocytes after binding of the carrier galactose residues to the asialoglycoprotein receptor. Since NAs, when set free from the carrier within hepatocytes, partly exit from these cells into the bloodstream, we considered the possibility that administration of galactosyl-terminating conjugates of NAs could result in plasma concentrations of these drugs that would be higher in liver sinusoids than in capillaries of other organs. In the present study we demonstrated the validity of this hypothesis. We injected rats with a conjugate of adenine arabinoside (ara-A) with lactosaminated poly-L-lysine and found that the plasma concentrations of ara-A were >2-fold higher in blood of liver than in systemic circulation. Liver blood was collected from the inferior vena cava after closing below and above the outflows of the hepatic veins. The present result suggests that conjugation with galactosyl-terminating peptides might be a way to selectively increase the concentrations of NAs not only in hepatocytes, which have the asialoglycoprotein receptor, but also in cells infiltrating the liver, such as neoplastic cells of micrometastases nourished by hepatic sinusoids.

Dynamic contrast-enhanced MR imaging of the upper abdomen: enhancement properties of gadobutrol, gadolinium-DTPA-polylysine, and gadolinium-DTPA-cascade-polymer.

The enhancement properties of gadobutrol (40 and 80 mumol/kg body weight, 550 daltons), gadolinium-DTPA-polylysine (20 mumol/kg body weight, 53,000 daltons) and gadolinium-DTPA-cascade-polymer (20 mumol/kg body weight, < 30,000 Daltons) were investigated in abdominal MR imaging using a pig model (n = 24). Signal intensities before and after contrast media application were assessed using a fast single slice FLASH sequence. Measurements were made every 4 s within the first 116 s, every minute between 4 and 10 min and after 15, 20, 30, 40, 50, 60, 90, and 120 min after contrast media injection. Injection of gadobutrol resulted in typical signal intensity curves characterizing it as an extracellular agent similar to gadopentetate dimeglumine. Significant enhancement was found in all tissues except the trunk muscles when the lower dose was administered. Gadolinium-DTPA-polylysine injection resulted also in significant enhancement of the liver, the pancreas, and the renal cortex, but not of the trunk muscle, reflecting its blood pool properties known also from other macromolecular contrast agents. The signal intensity curves obtained after gadolinium-DTPA-cascade-polymer injection were similar to those obtained after polylysine injection, stressing the blood pool character of this new type of blood pool agent.

Chemically optimized antimyosin Fab conjugates with chelating polymers: importance of the nature of the protein-polymer single site covalent bond for biodistribution and infarction localization.

Murine antimyosin Fab fragment was conjugated with 111In-labeled N-terminal-modified DTPA-polylysine using three bifunctional reagents: N-hydroxysuccinimide esters of 3-(2-pyridyldithio)propionic acid (SPDP conjugate), 4-(maleimidomethyl)cyclohexanecarboxylic acid (SMCC conjugate) and bromoacetic acid (BrAc conjugate) for potential localization of experimental myocardial infarction. Using various antibody preparations and a rabbit acute myocardial infarction model the following parameters were observed: (1) an in vitro antigen binding activity of SPDP conjugate = SMCC conjugate > BrAc conjugate, (2) a blood clearance rate of SPDP conjugate > BrAc conjugate > SMCC conjugate, (3) a liver and splenic accumulation of SPDP conjugate > BrAc conjugate > SMCC conjugate, and (4) the infarcted tissue activity showed an accumulation of SMCC conjugate > SPDP conjugate > BrAc conjugate. This study exemplifies the importance of rational chemical design of antimyosin Fab-chelating polymer conjugate for improved target tissue localization in vivo.