Phospholipid-based self-assembled mesophase systems for light-activated drug delivery.

The manipulation of the structure of phospholipid-based mesophases to induce a slow to fast drug release profile has potential for use in therapeutic situations where continuous absorption of drug is not desirable and reduce the frequency of injection for short acting or rapidly cleared drugs in treatments for diseases such as macular degeneration. This study had two aims; firstly to confirm the phase behaviour of 20 mol% cholesterol in 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphoethanolamine (POPE), which was previously reported to transition from lamellar (slow release) to bicontinuous cubic (fast release) phase with increasing temperature. Contrary to the literature, no bicontinuous cubic phase was observed but a transition to the inverse hexagonal phase occurred at all POPE : cholesterol ratios investigated. The second aim was to render these mesophases responsive to near-infrared laser (NIR) irradiation by incorporation of gold nanorods (GNR) incorporated into the POPE system to induce photothermal heating. The inclusion of 3 nM GNR in POPE systems induced reversible disruption of lipid packing equivalent to increasing the temperature to 55 °C when irradiated for 30 s. This study confirmed that although the previously published phase behavior was not correct, GNR and NIR can be used to manipulate the self-assembled mesophases in phospholipid-based systems and highlights the potential for a phospholipid-based light-activated drug delivery system.

The mesenteric lymph duct cannulated rat model: application to the assessment of intestinal lymphatic drug transport.

The intestinal lymphatic system plays key roles in fluid transport, lipid absorption and immune function. Lymph flows directly from the small intestine via a series of lymphatic vessels and nodes that converge at the superior mesenteric lymph duct. Cannulation of the mesenteric lymph duct thus enables the collection of mesenteric lymph flowing from the intestine. Mesenteric lymph consists of a cellular fraction of immune cells (99% lymphocytes), aqueous fraction (fluid, peptides and proteins such as cytokines and gut hormones) and lipoprotein fraction (lipids, lipophilic molecules and apo-proteins). The mesenteric lymph duct cannulation model can therefore be used to measure the concentration and rate of transport of a range of factors from the intestine via the lymphatic system. Changes to these factors in response to different challenges (e.g., diets, antigens, drugs) and in disease (e.g., inflammatory bowel disease, HIV, diabetes) can also be determined. An area of expanding interest is the role of lymphatic transport in the absorption of orally administered lipophilic drugs and prodrugs that associate with intestinal lipid absorption pathways. Here we describe, in detail, a mesenteric lymph duct cannulated rat model which enables evaluation of the rate and extent of lipid and drug transport via the lymphatic system for several hours following intestinal delivery. The method is easily adaptable to the measurement of other parameters in lymph. We provide detailed descriptions of the difficulties that may be encountered when establishing this complex surgical method, as well as representative data from failed and successful experiments to provide instruction on how to confirm experimental success and interpret the data obtained.

PEGylated interferon displays differences in plasma clearance and bioavailability between male and female mice and between female immunocompetent C57Bl/6J and athymic nude mice.

Gender and immune status can considerably impact on the pharmacokinetics (PK) of macromolecular and small molecule drugs. However, these effects are often not considered in drug development. We aimed to quantitatively evaluate effects of gender and immune status on the PK of PEGylated interferon in frequently used murine models. Chronically cannulated female athymic nude and female and male immunocompetent C57Bl/6J mice (n = 24 in total) received a single intravenous or subcutaneous (s.c.) dose of PEGylated interferon. Serial blood samples were taken for 48 h. Noncompartmental analysis and population PK modeling with covariate analysis were performed to evaluate the data. The PK of PEGylated interferon followed a three compartment disposition model with two sequential compartments for s.c. absorption. Female nude mice had significantly higher plasma clearance than C57Bl/6J mice (0.503 vs. 0.397 mL/h). Male mice had a slower absorption rate constant (0.138 h(-1)) and extent (46.2%) of s.c. absorption than female mice (0.274 in C57Bl/6J and 0.374 h(-1) in nude, 60.8% in both). Thus, gender and immune status significantly impacted on important PK parameters of PEGylated interferon in murine models commonly utilized in drug development. It is critical to take into account these differences when choosing animal models and conducting translational pharmacology research.

Practical lessons in murine thoracic lymph duct cannulations: observations in female and male mice across four different strains that impact on "cannulatability".

Cannulation of the thoracic lymph duct in experimental animals allows direct measurement of the lymphatic exposure of lymph-targeted drugs. When coupled with recent advances in genetically modified and diseased mouse models, this presents further opportunities to define changes in biological processes and disease in response to drug treatment. Although cannulation of the thoracic lymph duct in mice is inherently challenging because of the small size and delicate nature of the duct, it can be further confounded by anatomical variations between animals. In this communication, we present our observations on the anatomical features of the thoracic lymph duct between mice of different strains and genders, and discuss the impact of these features on the "cannulatability" of the duct. We also provide some technical tips to help guide other investigators to deliver higher experimental success rates.

The influence of intestinal lymphatic transport on the systemic exposure and brain deposition of a novel highly lipophilic compound with structural similarity to cholesterol.

OBJECTIVES: To assess the role of intestinal lymphatic transport in the oral bioavailability and brain deposition of a highly lipophilic, centrally acting drug candidate (Org 49209) in comparison to cholesterol, a close structural analogue. METHODS: The intestinal lymphatic transport of Org 49209 and cholesterol was assessed in lymph-cannulated anaesthetised rats and total bioavailability evaluated in non-lymph-cannulated animals. Parallel groups were employed to examine the brain deposition of Org 49209 after intraduodenal and intraperitoneal administrations. KEY FINDINGS: The contribution of intestinal lymphatic transport to total bioavailability was similar for Org 49209 and cholesterol (approximately 40% of the absorbed dose). However, the oral bioavailability of Org 49209 was significantly (fourfold) lower than cholesterol. Brain deposition of Org 49209 was similar after intraduodenal and intraperitoneal administration. Systemic exposure, however, was higher after intraduodenal administration and brain-to-plasma ratios were therefore reduced. CONCLUSION: The oral bioavailability of Org 49209 was significantly lower than that of its structural analogue cholesterol; however, intestinal lymphatic transport played a similar role in oral bioavailability for both compounds. Brain to plasma ratios were lower after intraduodenal versus intraperitoneal administration, suggesting that drug association with intestinal lymph lipoproteins may limit central nervous system access for highly lipophilic drugs.

The impact of lymphatic transport on the systemic disposition of lipophilic drugs.

This work investigates the influence of drug absorption route (intestinal lymphatics vs. blood supply) on drug pharmacokinetics and tissue distribution. To achieve this aim, the pharmacokinetics and tissue distribution of model compounds [1,1-bis(4-chlorophenyl)-2,2,2-trichloroethane, DDT; halofantrine] and lipids were assessed following intravenous delivery in lymph lipoproteins or plasma, and were found to differ significantly. For DDT, the clearance (CL) and volume of distribution (Vd ) were higher, whereas for halofantrine, CL and V(d) were lower, after entry in lymph versus plasma due, in particular, to differences in adipose tissue and liver uptake. In a recent study, halofantrine CL and V(d) were similar following entry in lymph or entry in plasma into the systemic circulation of animals predosed with lymph, whereas in the current study, predosing lymph did not influence DDT CL and V(d). For compounds such as DDT, changes to the route of absorption may thus directly impact on pharmacokinetics and tissue distribution, whereas for halofantrine factors that influence lymphatic transport may, by altering systemic lipoprotein concentrations, indirectly impact pharmacokinetics and tissue distribution. Ultimately, careful control of dosing conditions (formulation, prandial state), and thus the extent of lymphatic transport, may be important in assuring reproducible efficacy and toxicity for lymphatically transported drugs.

A mouse model to evaluate the impact of species, sex, and lipid load on lymphatic drug transport.

PURPOSE: To establish a lymph-cannulated mouse model, and use the model to investigate the impact of lipid dose on exogenous and endogenous lipid recruitment, and drug transport, into the lymph of males versus females. Finally, lymphatic transport and drug absorption in the mouse were compared to other pre-clinical models (rats/dogs). METHODS: Animals were orally or intraduodenally administered 1.6 mg/kg halofantrine in low or high (14)C-lipid doses. For bioavailability calculation, animals were intravenuosly administered halofantrine. Lymph or blood samples were taken and halofantrine, triglyceride, phospholipid and (14)C-lipid concentrations measured. RESULTS: Lymphatic lipid transport increased linearly with lipid dose, was similar across species and in male/female animals. In contrast, lymphatic transport of halofantrine differed markedly across species (dogs>rats>mice) and plateaued at higher lipid doses. Lower bioavailability appeared responsible for some species differences in halofantrine lymphatic transport; however other systematic differences were involved. CONCLUSIONS: A contemporary lymph-cannulated mouse model was established which will enable investigation of lymphatic transport in transgenic and disease models. The current study found halofantrine absorption and lymphatic transport are reduced in small animals. Future analyses will investigate mechanisms involved, and if similar trends occur for other drugs, to establish the most relevant model(s) to predict lymphatic transport in humans.

Intravenous dosing conditions may affect systemic clearance for highly lipophilic drugs: implications for lymphatic transport and absolute bioavailability studies.

The clearance (Cl) and volume of distribution (V(ss)) of a lipophilic, lymphatically transported drug, halofantrine (Hf) have been evaluated after intravenous delivery to the systemic circulation in ex vivo lymph and plasma, and compared with the data obtained after administration of a lipid-based emulsion and a lipid-free cosolvent formulation. Systemic Cl and V(ss) were significantly lower (approximately twofold) after delivery of Hf in lymph or the emulsion when compared with the administration in plasma or the cosolvent formulation. Preadministration of drug-free lymph, immediately before administration of drug in plasma, however, resulted in plasma profiles consistent with that obtained after administration of drug in lymph/emulsion. Where drug and lipid entered the systemic circulation coincidentally, systemic Cl of Hf, therefore, appeared to be relatively unaffected by the route of entry to the systemic circulation (i.e. via the lymph or the blood), but more significantly altered by total plasma lipid levels. Because temporal changes to plasma lipid levels occur as a result of the absorption of formulation or food-derived lipids and the infusion of intravenous lipid emulsions, the current data suggest that a mismatch in plasma lipid levels after intravenous and oral administrations may lead to differences in drug Cl and errors in bioavailability assessment.

Oral bioavailability assessment and intestinal lymphatic transport of Org 45697 and Org 46035, two highly lipophilic novel immunomodulator analogues.

Org 45697 (MW 600.7, clogP 7.92, soybean oil solubility 50 mg/g) and Org 46035 (MW 601.6, clog P 8.46, soybean oil solubility 40 mg/g) are two poorly water soluble (<0.1 microg/ml), highly lipophilic drug candidates with immunomodulator activity and highly analogous chemical structures. After oral administration to conscious ambulatory rats in an aqueous-based methylcellulose/Tween 80 suspension, the bioavailability of both compounds was low (< 2% of administered dose). However, bioavailability was significantly increased (> 5 fold) after oral administration in a long chain triglyceride lipid (olive oil) formulation. Subsequent studies have explored the potential for solubilising formulations, including lipid-based formulations, to enhance the oral bioavailability of Org 45697 and Org 46035 and secondly to explore the potential contribution of intestinal lymphatic transport to intestinal absorption. The experimental data show that solubilising formulations may provide for significant increases in oral bioavailability for Org 45697 and Org 46035 and that after co-administration with lipid, 35-50% of the absorbed dose may be transported to the systemic circulation via the intestinal lymph. Interestingly, the lymphatic transport of the less lipid soluble analogue, Org 46035 was approximately 40% lower than that of Org 45697 suggesting that relatively subtle differences in lipid solubility can have significant impact on the extent of lymphatic transport.