Nanomedicine for Improved Efficacy of Tuberculosis Drugs Pharmacokinetic importance

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Transcription:

Nanomedicine for Improved Efficacy of Tuberculosis Drugs Pharmacokinetic importance Emerging Researcher Symposium Dr. Rose Hayeshi 10 October 2012

Outline Challenges in TB treatment Nanomedicine as proposed solution Results Conclusions CSIR 2012 Slide 2

Challenges for TB therapy One-third infected worldwide with 1.4 M deaths in 2010 TB is a leading killer in SA Worsening due to Treat. failure & HIV co-infection South Africa is among the high burden TB and MDR-TB countries worldwide Lengthy treatment (6-9 months) Daily handful dose Patient non-compliance 14 Tablets everyday for 2 years CSIR 2012 Slide 3

TB burden in South Africa South Africa accounted for 25% new and relapse cases of TB in Africa in 2010 TB incidence rates stable/falling in all high incidence countries except in South Africa CSIR 2012 Slide 4

TB drug pipeline not promising TB drug pipeline (TB global alliance) Novartis cancer drug pipeline http://www.novartisoncology.com/research-innovation/pipeline.jsp http://www.tballiance.org/pipeline/pipeline.php 90% chance of rejection in early-stage phase I clinical trials; 50% chance in phase II; Phase III drugs in TB pipeline can only replace 1 or 2 of the current drugs CSIR 2012 Slide 5

Proposed solution to the challenges of TB treatment More efficient drugs and drug delivery system with improved pharmacokinetics Address non compliance, Minimise toxicity, Reduce emergence of drug resistance Shorten treatment time Nanoparticle based drug delivery system (nanomedicine) CSIR 2012 Slide 6

Pharmacokinetics (PK) Pharmacokinetics is the quantification of absorption, distribution, metabolism and excretion (ADME) Dictates availability of drug molecule at site of action CSIR 2012 Slide 7

Nanomedicine Application of nanotechnology in health Nanosized drug delivery systems for treatment Journal of Leukocyte Biology Volume 78, September 2005 CSIR 2012 Slide 8

Kinetics of nanoparticles influenced by Size Higher drug loading Solubility Large surface area Allows intracellular uptake nm size range particles more efficiently taken up than microparticles Charge Surface charge influences plasma protein binding and cellular uptake Surface chemistry PEG on surface increases blood circulation time CSIR 2012 Slide 9

Pharmacokinetic advantages of nanomedicine Enhanced drug stability High carrying capacity Hydrophilic/hydrophobic substances Enhance absorption and bioavailability Reduce clearance Minimised first pass metabolism Increase in drug half life prolonged effect Through slow release can reduce dosage and dose frequency Selective uptake by tissues (passive targeting) Delivery through lymphatic system Target specific tissue and cells (active targeting) Conventional drugs Nano-based drugs CSIR 2012 Slide 10

Plasma Conc. (ug / ml) Objectives Sustained release Conventional therapy Toxic level MIC Improve the PK of anti-tb drugs Sustained release Improve solubility and half-life Reduce dose frequency Polymer degradation: Sustained release over days Reduce dose Deliver drug at site of action Reduce treatment time and cost 6-9 months: potentially 2 months Current drugs cost: 1% of the total treatment management CSIR 2012 Slide 11

Nanoparticles encapsulating anti-tb drugs (Nanodrug) Successfully nano encapsulated 4 of the first line anti-tb drugs Isoniazid (INH), Rifampicin (RIF), Pyrazinamide (PZA) and Ethambutol (ETB) Poly (lactide-co-glycolide) (PLGA) polymer Double emulsion solvent evaporation - spray drying technique Properties: 250 nm average size Highly reproducible production Scalable (known pharmaceutical process equipment) Narrow size distribution (polydispersity < 0.1-0.3) Controllable surface charge Modified surface Increase circulation time: PEG Enhance particle uptake: Chitosan CSIR 2012 Slide 12

Plasma circulation and biodistribution Biodistribution of Rhodamine labelled PLGA nanoparticles coated with 1% PEG or Pluronics F127. 7 days after oral administration. LUNGS LIVER KIDNEY SPLEEN BRAIN CSIR 2012 Slide 13

Pharmacokinetics in unchallenged mice Sustained release of RIF and INH from PLGA nanoparticles Increase in drug half-life Potential for dose frequency reduction CSIR 2012 Slide 14

How does altered PK affect efficacy? Female C57BI/6 mice models of TB H37Rv at 50-100 cfu/lung Aerosol infection Day 0 Confirmation of infection dose Day 1 Determination of established burden 1 x 10 5 1 x 10 6 cfu/lung 3 x 10 3 cfu/spleen W3 INH/RIF/PZA daily Nano- INH/RIF/PZA once a week Nanoparticles only Untreated W7, W9, W12 INH = 5 mg/kg RIF = 10 mg/kg PZA = 20 mg/kg Data analysis Bodyweight (weekly) Lung weight Pulmonary bacilli burden Splenic bacilli burden Pulmonary pathology CSIR 2012 Slide 15

Effects of the Nanodrug on Mycobacaterium tuberculosis replication Lung CFU Spleen CFU 1.0 10 6 1.0 10 5 1.0 10 4 1.0 10 3 1.0 10 2 1.0 10 1 1.0 10 0 1.0 10-1 1.0 10 5 1.0 10 4 1.0 10 3 1.0 10 2 1.0 10 1 1.0 10 0 0 5 10 15 Weeks UT-Control NP-Control CT-w ater CT-NP 0 5 10 15 Weeks UT-Control NP-Control CT-w ater CT-NP Nanodrug once a week vs conventional drug daily Treatment with nanoencapsulated TB drugs once a week, comparable to daily treatment with conventional drugs CSIR 2012 Slide 16

Pulmonary pathology Untreated control Nanoparticle control RIF/INH/PZA daily Nano RIF/INH/PZA once a week CSIR 2012 Slide 17

Increased circulation and slow release Biodistribution of Rhodamine labelled PLGA nanoparticles coated with 1% PEG or Pluronics F127. 7 days after oral administration. Slow release leading to increase in half-life CSIR 2012 Slide 18

Conclusion Nanoencapsulated anti-tb drugs as effective as conventional drugs at fraction of dose Implications of nanomedicine to improve TB drugs, Reduction in the dose frequency, Promoting patient compliance to treatment Targeting next step to reduce dose Generic technology Can be applied to malaria, HIV and other poverty related diseases affecting Africa CSIR 2012 Slide 19

Acknowledgements CSIR conference organising committee Dr. Muazzam Jacobs, University of Cape Town for the efficacy study CSIR Encapsulation and Delivery group Prof. Anne Lenaerts, CSU Local and international collaborators Department of Science and Technology, South Africa CSIR 2012 Slide 20

Thank you

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