Structure activity relationship of dendrimer microbicides with dual action antiviral activity.

BACKGROUND: Topical microbicides, used by women to prevent the transmission of HIV and other sexually transmitted infections are urgently required. Dendrimers are highly branched nanoparticles being developed as microbicides. However, the anti-HIV and HSV structure-activity relationship of dendrimers comprising benzyhydryl amide cores and lysine branches, and a comprehensive analysis of their broad-spectrum anti-HIV activity and mechanism of action have not been published. METHODS AND FINDINGS: Dendrimers with optimized activity against HIV-1 and HSV-2 were identified with respect to the number of lysine branches (generations) and surface groups. Antiviral activity was determined in cell culture assays. Time-of-addition assays were performed to determine dendrimer mechanism of action. In vivo toxicity and HSV-2 inhibitory activity were evaluated in the mouse HSV-2 susceptibility model. Surface groups imparting the most potent inhibitory activity against HIV-1 and HSV-2 were naphthalene disulfonic acid (DNAA) and 3,5-disulfobenzoic acid exhibiting the greatest anionic charge and hydrophobicity of the seven surface groups tested. Their anti-HIV-1 activity did not appreciably increase beyond a second-generation dendrimer while dendrimers larger than two generations were required for potent anti-HSV-2 activity. Second (SPL7115) and fourth generation (SPL7013) DNAA dendrimers demonstrated broad-spectrum anti-HIV activity. However, SPL7013 was more active against HSV and blocking HIV-1 envelope mediated cell-to-cell fusion. SPL7013 and SPL7115 inhibited viral entry with similar potency against CXCR4-(X4) and CCR5-using (R5) HIV-1 strains. SPL7013 was not toxic and provided at least 12 h protection against HSV-2 in the mouse vagina. CONCLUSIONS: Dendrimers can be engineered with optimized potency against HIV and HSV representing a unique platform for the controlled synthesis of chemically defined multivalent agents as viral entry inhibitors. SPL7013 is formulated as VivaGel(R) and is currently in clinical development to provide protection against HIV and HSV. SPL7013 could also be combined with other microbicides.

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.

Synthesis of bivalent beta2-adrenergic and adenosine A1 receptor ligands.

Research in the area of simutaneously targeting more than one G protein-coupled receptor (GPCR) has increased in recent times. By exploiting the cross talk between the beta2-adrenergic (beta2AR) and adenosine A1 receptors (A1AR) on adenylate cyclase activity, we synthesized a series of bivalent agonists for both GPCRs to generate responses from more than one receptor. We have demonstrated a relationship between the various beta2-adrenergic and A1 adenosine bivalent parameters of linker and bifunctionality by using data that are drawn from in vitro assays. The hexyl-linked 12e (K(i), 311 nM) and butyl-linked 12c ( K(i), 863 nM) bivalent compounds displayed reasonable binding affinities for the beta2AR when compared with the control (-)isoproterenol (K(i), 136 nM), and both compounds also exhibited a persuasive bifunctional trend for both receptors at various drug concentrations. The bivalent compound 12e was also found to have significant EC50 potency (6 nM) at the beta2AR in DDT cells.

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.

Impact of surface derivatization of poly-L-lysine dendrimers with anionic arylsulfonate or succinate groups on intravenous pharmacokinetics and disposition.

Tritium-labeled poly- l-lysine dendrimers displaying 8 or 16 surface lysines have been capped with benzene sulfonate (BS), benzene disulfonate (BDS), or succinate (Succ) groups, and the intravenous pharmacokinetics and disposition profiles of the resulting dendrimers (Lys(8)(BS)(16), Lys(16)(BS)(32), Lys(16)(BDS)(32), Lys(16)(Succ)(32)) have been evaluated. Lys(16)(Succ)(32) was rapidly removed from the plasma primarily via renal elimination. Lys(16)(BS)(32) and Lys(16)(BDS)(32) were opsonized, resulting in more prolonged plasma elimination kinetics and increased uptake by the liver. Data obtained at higher doses suggested some evidence of nonlinear pharmacokinetics. Lys(8)(BS)(16) had reduced affinity for plasma proteins and was cleared more rapidly than the larger Lys(16)(BS)(32) or Lys(16)(BDS)(32) dendrimers. Lys(8)(BS)(16) and Lys(16)(BS)(32) were metabolized in vivo, resulting in the production of a low molecular weight species (possibly the cleavage product Lys(BS) (2)) that was extensively renally eliminated and accounted for almost all of the radioactivity recovered in urine ( approximately 20-45% of administered (3)H). In contrast, only 3-5% of the administered (3)H was recovered in the urine of rats administered Lys(16)(BDS)(32), suggesting increased resistance to in vivo degradation. The plasma clearance, distribution, and metabolic profiles of lysine dendrimers are therefore significantly influenced by the structure and charge of the capping groups. In particular, larger arylsulfonate-capped lysine dendrimers are rapidly opsonized and initially cleared from the plasma by the reticuloendothelial organs. The degree of metabolism is subsequently dictated by the nature of the surface capping group with BDS surfaces seemingly more resistant to breakdown. In contrast, smaller arylsulfonate-capped dendrimers are less readily opsonized and phagocytozed but are metabolically labile, and succinate-capped dendrimers are rapidly eliminated by the kidneys.

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.

Dendrimers as drugs: discovery and preclinical and clinical development of dendrimer-based microbicides for HIV and STI prevention.

Starpharma focuses on the use of dendrimers as drugs in their own right, in contrast to dendrimers as drug delivery vehicles or diagnostics. This contextual review describes how dendrimers offer a unique platform for exploring chemical diversity on the nanoscale and how the production of dendrimer libraries covering a diverse array of macromolecular structures can be used in drug discovery and development. Using Starpharma's work on the prevention of HIV and sexually transmitted infections (STIs) through the development of microbicide candidates as an example, the process from which SPL7013 emerged as a development candidate is described. Following a range of preclinical studies, Starpharma submitted an investigational new drug application (IND) for SPL7013 gel (VivaGel) to the United States Food and Drug Administration (FDA) in June 2003, the first such submission for a dendrimer-based drug. The first clinical trial under this IND was completed in 2004.