A NOVEL ALTERNATIVE “MORNING AFTER” LOCAL ...population is unclear, unpublished data from our...
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A novel alternative “morning after” local administration approach for post-exposure prophylaxis of HIV C. Sanders 1 , V. Taresco 2 , R. Cavanagh 1 , M. J. Stocks 1 , P. M. Fischer 1 , C. Alexander 1 , P. Gershkovich 1 1 School of Pharmacy, University of Nottingham, Nottingham UK. 2 School of Chemistry, University of Nottingham, Nottingham, UK. Contact email: [email protected] INTRODUCTION Since 2013 the number of newly diagnosed cases of HIV has practically remained unchanged (1). Current post-exposure prophylaxis (PEP) involves an oral administration, often with considerable side effects. Under WHO guidelines, PEP in a sexual exposure (PEPSE) is limited to only high-risk scenarios (2). The size of the population exposed to low to moderate risk scenarios is unclear. AIM The overarching aim of this project is to develop a nanoparticle-based PEPSE with a significant drug loading, for local rectal administration after a low to moderate risk sexual exposure. METHODS • Dolutegravir was selected the antiviral of choice. It was then chemically modified, producing a dolutegravir myristate (MDTG) (Figure 1.) • A two-step nanoprecipitation system was designed (Figure 2). Three testing conditions were assessed, using different coating masses of mPEG5000-LA100 (Figure 3). • Biocompatibility at 24 hours was on Caco-2 and Raw 264.7 cells. Uptake was traced by substituting 10% of the total nano-carrier with a Cy5 Blue labelled PEG5000. (Figure 3). RESULTS CONCLUSIONS/FUTURE WORK • Due to the 14-carbon chain in MDTG, it can be successfully self-assembled into an unstable nanocrystal through a nanoprecipitation set up. Once in this form, it can be coated with a polymer agent, in a second nanoprecipitation. • Nanoformulations with a high drug content (above 50% wt%) of MDTG were developed. In vitro data suggests that uptake is higher in Raw 264.7 macrophage than Caco-2 cells at 24 hours. Target cells for this formulation are macrophages and antigen presenting cells, thus the results are encouraging. • More complex in vitro models such as Caco-2/M cells co-culture need to be investigated to provide more physiological relevant uptake data. Figure 4. TEM images taken at 8 hours after precipitation of MDTG. A): Image taken at 105K magnification. B): Image taken at 87K magnification. • MDTG can be precipitated into an unstable nanocrystal (Figure 4). • All formulations developed contained a significant drug content with a final average of 215nm in size (Figures 5-6). • The coated formulation with 0.22mg was chosen to test further as it carried a significant drug content. • In vitro data suggests biocompatibility and internalization of the formulation in target cells. Therefore providing potential for drug delivery (Figures 7-9). REFERENCES 1. HIV/AIDS JUNPo. UNAIDS DATA 2018. UNAIDS/JC2929E. 2018 ed2018 2. December 2018 Supplement to the 2016 Consolidated Guidelines on the use of Antiretroviral Drugs for Treating and Preventing HIV infection. Geneva: World Health Organization; 2014 (https://www.who.int/hiv/pub/guidelines/arv2013/arvs2013upplement_dec2014/en/, accessed 6 January 2020). 3. B. Sillman et al., Creation of a long-acting nanoformulated dolutegravir. Nature Communications 9, 443 (2018). Figure 5. Representative TEM images of a formulation coated with mPEG5000-La100 0.22 mg coating per vial. A) and B) were taken 12 hours post-coating. A) Image taken at 16.5K magnification. B)Image taken at 43K magnification. Figure 9. Quantative uptake at 24 hours on Raw 264.7 and Caco-2 cell lines. Data presented as mean ± S.D (N=3, n=3). Unpaired T student test was statistically significant (*, p=<0.05). Figure 7. Biocompatibility data on Raw 264.7 and Caco-2 cell lines at 24 hours. Panel A shows LDH release on Caco-2 cells. Panel B shows LDH release on Raw 264.7 cells. Panel C shows metabolic activity assessed by Presto Blue on Caco-2 cells. Panel D shows metabolic activity assessed by Presto Blue on Caco-2 cells. Data presented as mean ± S.D (N=3, n=3) Figure 8. Micrographs of particle internalization in Caco-2 intestinal cells and RAW 264.7 macrophage cells. Particles dosed at 50 ug/ml (polymer concentration) for 24 hours. Scale bar = 50 um. 0.001 0.01 0.1 1 10 100 1000 0 25 50 75 100 [Dolutegravir] ( M) LDH release (% total cystolic LDH) MDTG mPEG5000-LA-100 0.22mg formulation MDTG nanocrystal Caco-2 0.001 0.01 0.1 1 10 100 1000 0 25 50 75 100 [Dolutegravir] ( M) LDH release (% total cystolic LDH) MDTG mPEG5000-LA-100 0.22mg Formulation MDTG nanocrystal Raw 264.7 10 -4 10 -3 10 -2 10 -1 10 0 10 1 10 2 10 3 0 25 50 75 100 [Dolutegravir] ( M) Metabolic activity (%) MDTG mPEG5000-LA-100 0.22mg formulation MDTG Nanocrystal Dolutegravir Caco-2 10 -4 10 -3 10 -2 10 -1 10 0 10 1 10 2 10 3 0 25 50 75 100 [Dolutegravir] ( M) Metabolic activity (%) MDTG MDTG nanocrystal mPEG5000-LA-100 0.22mg formulation Dolutegravir Raw 264.7 Biocompatibility A B C D Figure 3. Chemical structure of the polymers used. A) mPEG-LA (122:200) mw 5000 da. B) Cy5 Blue labelled PEG 5000. Figure 1. Synthesis of MDTG. Modified reaction from Sillman et al (3). Figure 2. Schematic depiction of the solvent diffusion method used to precipitate and subsequently coat the nanocrystals with mPEG5000-La100. B) 200nm A) 200nm 1000n m A) 500nm B) 0.22MG COATING per vial 0.44MG COATING per vial 1MG COATING per vial MDTG Nanocrystals 0 100 200 300 191 217 231 225 Size by DLS ns ✱✱ 0.22MG COATING per vial 0.44MG COATING per vial 1MG COATING per vial 0 20 40 60 80 100 62 50 73 wt% by HPLC-UV ✱✱ A) B) Figure 6. DLS measurements and drug content (expressed as wt%) of the formulations produced. N=6 for each group. Error bars indicate SD of the mean. A) Anova test between groups is significant (p<0.0001). However no statistical difference is found between formulations. B) Wt% of the formulations developed measured by HPLC-UV. The difference between groups is significant after an Anova test (p=<0.0005). Post hoc analysis are displayed on the graph. Caco-2 cell line RAW 264.7 cell line 0 20 40 60 80 100 71 43 24 hour uptake study Formulation uptake (pg/cell) ✱
Transcript of A NOVEL ALTERNATIVE “MORNING AFTER” LOCAL ...population is unclear, unpublished data from our...
A novel alternative “morning after” local administration approach for post-exposure prophylaxis of HIV
C. Sanders 1, V. Taresco2, R. Cavanagh1, M. J. Stocks1, P. M. Fischer1, C. Alexander1, P. Gershkovich1
1School of Pharmacy, University of Nottingham, Nottingham UK. 2School of Chemistry, University of Nottingham, Nottingham, UK.
Contact email: [email protected]
INTRODUCTION
Since 2013 the number of newly diagnosed cases of HIV has practically remained unchanged (1).Current post-exposure prophylaxis (PEP) involves an oral administration, often with considerable sideeffects. Under WHO guidelines, PEP in a sexual exposure (PEPSE) is limited to only high-risk scenarios(2). The size of the population exposed to low to moderate risk scenarios is unclear.
AIM
The overarching aim of this project is to developa nanoparticle-based PEPSE with a significantdrug loading, for local rectal administration aftera low to moderate risk sexual exposure.
METHODS
• Dolutegravir was selected the antiviral ofchoice. It was then chemically modified,producing a dolutegravir myristate (MDTG)(Figure 1.)
• A two-step nanoprecipitation system wasdesigned (Figure 2). Three testing conditionswere assessed, using different coating massesof mPEG5000-LA100 (Figure 3).
• Biocompatibility at 24 hours was on Caco-2 andRaw 264.7 cells. Uptake was traced bysubstituting 10% of the total nano-carrier witha Cy5 Blue labelled PEG5000. (Figure 3).
RESULTS
CONCLUSIONS/FUTURE WORK• Due to the 14-carbon chain in MDTG, it can be successfully self-assembled into an unstable nanocrystal through a nanoprecipitation set up. Once in this form, it can be
coated with a polymer agent, in a second nanoprecipitation.
• Nanoformulations with a high drug content (above 50% wt%) of MDTG were developed. In vitro data suggests that uptake is higher in Raw 264.7 macrophage than Caco-2cells at 24 hours. Target cells for this formulation are macrophages and antigen presenting cells, thus the results are encouraging.
• More complex in vitro models such as Caco-2/M cells co-culture need to be investigated to provide more physiological relevant uptake data.
Figure 4. TEM images taken at 8 hours after precipitation of MDTG. A): Imagetaken at 105K magnification. B): Image taken at 87K magnification.
• MDTG can be precipitated into an unstable nanocrystal (Figure 4).
• All formulations developed contained a significant drug content with a final average of 215nm in size (Figures 5-6).
• The coated formulation with 0.22mg was chosen to test further as it carried a significant drug content.
• In vitro data suggests biocompatibility and internalization of the formulation in target cells. Therefore providing potential for drug delivery (Figures 7-9).
REFERENCES1. HIV/AIDS JUNPo. UNAIDS DATA 2018. UNAIDS/JC2929E. 2018 ed20182. December 2018 Supplement to the 2016 Consolidated Guidelines on the use of Antiretroviral Drugs for Treating and Preventing HIV infection. Geneva: World Health Organization; 2014 (https://www.who.int/hiv/pub/guidelines/arv2013/arvs2013upplement_dec2014/en/, accessed 6 January
2020).3. B. Sillman et al., Creation of a long-acting nanoformulated dolutegravir. Nature Communications 9, 443 (2018).
Figure 5. Representative TEM images of a formulation coated withmPEG5000-La100 0.22 mg coating per vial. A) and B) were taken 12 hourspost-coating. A) Image taken at 16.5K magnification. B)Image taken at 43Kmagnification.
Figure 9. Quantative uptake at 24 hours on Raw 264.7 and Caco-2 cell lines.Data presented as mean ± S.D (N=3, n=3). Unpaired T student test wasstatistically significant (*, p=<0.05).
Figure 7. Biocompatibility data on Raw 264.7 and Caco-2 cell lines at 24 hours. Panel Ashows LDH release on Caco-2 cells. Panel B shows LDH release on Raw 264.7 cells. Panel Cshows metabolic activity assessed by Presto Blue on Caco-2 cells. Panel D shows metabolicactivity assessed by Presto Blue on Caco-2 cells. Data presented as mean ± S.D (N=3, n=3)
Figure 8. Micrographs of particle internalization in Caco-2 intestinal cellsand RAW 264.7 macrophage cells. Particles dosed at 50 ug/ml (polymerconcentration) for 24 hours. Scale bar = 50 um.
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Figure 3. Chemical structure of the polymers used. A) mPEG-LA (122:200)mw 5000 da. B) Cy5 Blue labelled PEG 5000.
Figure 1. Synthesis of MDTG. Modified reaction from Sillman et al (3).
Figure 2. Schematic depiction of the solvent diffusion method used toprecipitate and subsequently coat the nanocrystals with mPEG5000-La100.
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