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Volume 08

Clinical Pharmacology & Biopharmaceutics

ISSN: 2167-065X

Pharmacology 2019

World Heart Congress 2019

August 19-20, 2019

JOINT EVENT

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August 19-20, 2019 Vienna, Austria

&

7

th

World Heart Congress

24

th

World Congress on

Pharmacology

The effects of inhaled Rapamycin solid lipid particle size on transport across lung epithelial cells

Emelie Land, Lyn M. Moir, Daniela Traini, Paul M. Young

and

Hui Xin Ong

The University of Sydney, Australia

Background

: Lymphangioleiomyomatosis (LAM) is a rare lung disease characterized by the uncontrolled growth

of smooth like muscle cells (LAM cells) in the lungs that can spread to other body parts via the lymphatic system

Current treatment for LAM is oral Rapamycin, which is limited by its low bioavailability (~15%) and side effects

[1, 2]. It’s been shown that particles of approximately <1000nm with a negative surface charge are able to enter the

lymphatic system [3].

Aim

: The current study aimed to determine the optimum size of Rapamycin solid lipid nanoparticles (SLN) that will

facilitate drug entry into the lymphatic system through the inhaled route in order to increase lung bioavailability,

reduce systemic side effects and potentially have increased efficacy.

Methods

: Three different sized (1-3) of Rapamycin-SLN: 200, 500 and 800nm, were produced by dissolving

Rapamycin and glyceryl behenate in methanol and dichloromethane. The organic solvents were evaporated prior to

mixing with hot Tween80 (1.5 %w/v) solution. The solution was either homogenized (1700rpm) or passed through

a membrane with specified pore sizes mini-extruder before being freeze-dried overnight. Size and charge were

determined using a Zetasizer. Transepithelial drug transport of the formulations was evaluated

in-vitro

using a Calu-

3 air-liquid interface bronchial epithelial cell model.

Results

: All Rapamycin-SLNs formulations had negative surface charge (table 1) and average particle sizes: 237 ±

1.8nm, 583 ± 1.3nm and 790 ± 2.3nm, respectively. The formulations showed varying encapsulation efficiencies

ranging from 65.8 to 97.32%. The transport studies showed that 83 ± 4.2% and 68 ± 2.5 % of SLN200 and SLN500

formulations were transported, respectively, across the epithelium after 4hrs compared to 22 ± 2.15% of the SLN800

formulation.

Conclusion & Discussion

: The current study showed that Rapamycin-SLN with negative surface charge and size of

approximately 200nm is able to cross the lung epithelium faster than larger particles. Future studies will be expanded

to evaluate the entry of these SLN particles

Recent Publications:

1.

Smolarek, T.A., et al., Evidence that lymphangiomyomatosis is caused by TSC2mutations: chromosome 16p13

loss of heterozygosity in angiomyolipomas and lymph nodes from women with lymphangiomyomatosis. Am

J Hum Genet, 1998. 62(4): p. 810-5.

2.

Kumasaka, T., et al., Lymphangiogenesis-mediated shedding of LAM cell clusters as a mechanism for

dissemination in lymphangioleiomyomatosis. Am J Surg Pathol, 2005. 29(10): p. 1356-66.

3.

Videira, M.A., et al., Lymphatic uptake of pulmonary delivered radiolabelled solid lipid nanoparticles. J Drug

Target, 2002. 10(8): p. 607-13.

Biography

Emelie Landh completed her Bachelor in Medical Sciences, majoring in Pharmacology at the University of Sydney in 2013. She went on to complete a Graduate

Diploma in Pharmacology with the Respiratory Technology Group at the Woolcock Institute of Medical research at the University of Sydney in 2014. She is

currently at the end of the second year of her PhD under the supervision of Dr. Hui Xin Ong with the Respiratory Technology Group. Her PhD project involves

developing an inhaled combination treatment using Solid-Lipid Nanoparticles for treating Lymphangioleiomyomatosis (LAM).

Emelie Land et al., Clin Pharmacol Biopharm, Volume 08