Tuning HIV drug release from a nanogel-based in situ forming implant by changing nanogel size.

HIV is a global public health threat and requires life-long, daily oral dosing to effectively treat. This pill burden often results in poor adherence to the medications. An injectable in situ forming implant with tuneable drug release kinetics would allow patients to replace some of their daily pills with a single infrequent injection. In this work, we investigate how the size of poly(N-isopropylacrylamide) (polyNIPAm) nanogels influences the long-acting release behaviour of the HIV drug lopinavir from an in situ forming implant. Four sizes of polyNIPAm nanogels were prepared with mean diameters of 65, 160, 310 and 450 nm as characterised by dynamic light scattering. These nanogels all displayed synergistic dual stimuli responsive behaviour by aggregating only upon heating above 31 °C at physiological ionic strength. Mixing the nanogels with solid drug nanoparticles (SDNs) of lopinavir and exposing this concentrated dispersion to physiological temperature and ionic strength resulted in the in situ formation of nanocomposite implants. Three different loadings of the SDNs (33, 50 and 66% w/w) with each of the nanogels were prepared. The drug release behaviour and stability of these nanocomposite implants were then assessed in vitro over 360 hours. All samples displayed a single phase of drug release and application of the Ritger-Peppas equation indicated Fickian diffusion. Nanocomposites with the lowest loading of SDNs (33%) showed a linear relationship between nanogel diameter and the dissolution constant. These results show an attractive method for tuning the release of lopinavir from in situ loading implants with high drug loadings.

[1]  T. Shapiro,et al.  Long-acting injectable atovaquone nanomedicines for malaria prophylaxis , 2018, Nature Communications.

[2]  D. Podzamczer,et al.  Long-acting intramuscular cabotegravir and rilpivirine in adults with HIV-1 infection (LATTE-2): 96-week results of a randomised, open-label, phase 2b, non-inferiority trial , 2017, The Lancet.

[3]  Tom O. McDonald,et al.  Dual-stimuli responsive injectable microgel/solid drug nanoparticle nanocomposites for release of poorly soluble drugs. , 2017, Nanoscale.

[4]  L. H. Lima,et al.  Ocular Biocompatibility of Poly-N-Isopropylacrylamide (pNIPAM) , 2016, Journal of ophthalmology.

[5]  Darren L. Smith,et al.  Accelerated oral nanomedicine discovery from miniaturized screening to clinical production exemplified by paediatric HIV nanotherapies , 2016, Nature Communications.

[6]  J. S. Suk,et al.  Mucus‐Penetrating Nanosuspensions for Enhanced Delivery of Poorly Soluble Drugs to Mucosal Surfaces , 2016, Advanced healthcare materials.

[7]  S. Rannard,et al.  Strengths, weaknesses, opportunities and challenges for long acting injectable therapies: Insights for applications in HIV therapy. , 2016, Advanced drug delivery reviews.

[8]  R. Prud’homme,et al.  Polymeric nanoparticles and microparticles for the delivery of peptides, biologics, and soluble therapeutics. , 2015, Journal of controlled release : official journal of the Controlled Release Society.

[9]  Lulu Wang,et al.  Nanosuspensions of poorly water-soluble drugs prepared by bottom-up technologies. , 2015, International journal of pharmaceutics.

[10]  M. Markowitz,et al.  High Interest in a Long-Acting Injectable Formulation of Pre-Exposure Prophylaxis for HIV in Young Men Who Have Sex with Men in NYC: A P18 Cohort Substudy , 2014, PloS one.

[11]  U. Gasser,et al.  Form factor of pNIPAM microgels in overpacked states. , 2014, The Journal of chemical physics.

[12]  R. Bodmeier,et al.  In situ forming implants for the delivery of metronidazole to periodontal pockets: formulation and drug release studies , 2014, Drug development and industrial pharmacy.

[13]  Darren L. Smith,et al.  Antiretroviral Solid Drug Nanoparticles with Enhanced Oral Bioavailability: Production, Characterization, and In Vitro–In Vivo Correlation , 2014, Advanced healthcare materials.

[14]  David S Jones,et al.  Solvent induced phase inversion-based in situ forming controlled release drug delivery implants. , 2014, Journal of controlled release : official journal of the Controlled Release Society.

[15]  A. Chilkoti,et al.  A depot-forming glucagon-like peptide-1 fusion protein reduces blood glucose for five days with a single injection. , 2013, Journal of controlled release : official journal of the Controlled Release Society.

[16]  Tom O. McDonald,et al.  High-throughput nanoprecipitation of the organic antimicrobial triclosan and enhancement of activity against Escherichia coli. , 2013, Journal of materials chemistry. B.

[17]  H. E. Canavan,et al.  Assessment of cytotoxicity of (N-isopropyl acrylamide) and Poly(N-isopropyl acrylamide)-coated surfaces , 2013, Biointerphases.

[18]  To Ngai,et al.  Microgel particles: The structure‐property relationships and their biomedical applications , 2013 .

[19]  B. Alexander,et al.  Characterization of thermo and pH responsive NIPAM based microgels and their membrane blocking potential , 2013 .

[20]  C. Osuji,et al.  Role of interparticle attraction in the yielding response of microgel suspensions , 2013 .

[21]  Liandong Hu,et al.  An overview of preparation and evaluation sustained-release injectable microspheres , 2013, Journal of microencapsulation.

[22]  Jong Hoon Park,et al.  Long-acting injectable formulations of antipsychotic drugs for the treatment of schizophrenia , 2013, Archives of pharmacal research.

[23]  B. Jeong,et al.  Recent progress of in situ formed gels for biomedical applications , 2013 .

[24]  P. Cremer,et al.  Fluorescence modulation sensing of positively and negatively charged proteins on lipid bilayers , 2013, Biointerphases.

[25]  Sabine Kempe,et al.  In situ forming implants - an attractive formulation principle for parenteral depot formulations. , 2012, Journal of controlled release : official journal of the Controlled Release Society.

[26]  D. Burgess,et al.  Accelerated in‐vitro release testing methods for extended‐release parenteral dosage forms , 2012, The Journal of pharmacy and pharmacology.

[27]  Yanbing Zhao,et al.  The dual temperature/pH-sensitive multiphase behavior of poly(N-isopropylacrylamide-co-acrylic acid) microgels for potential application in in situ gelling system. , 2011, Colloids and surfaces. B, Biointerfaces.

[28]  H. Byrne,et al.  Intracellular localisation, geno- and cytotoxic response of polyN-isopropylacrylamide (PNIPAM) nanoparticles to human keratinocyte (HaCaT) and colon cells (SW 480). , 2010, Toxicology letters.

[29]  Byung Soo Kim,et al.  A biodegradable, injectable, gel system based on MPEG-b-(PCL-ran-PLLA) diblock copolymers with an adjustable therapeutic window. , 2010, Biomaterials.

[30]  A. D’Avolio,et al.  An HPLC-PDA Method for the Simultaneous Quantification of the HIV Integrase Inhibitor Raltegravir, the New Nonnucleoside Reverse Transcriptase Inhibitor Etravirine, and 11 Other Antiretroviral Agents in the Plasma of HIV-Infected Patients , 2008, Therapeutic drug monitoring.

[31]  F. Lampe,et al.  Adherence to antiretroviral treatment in patients with HIV in the UK: a study of complexity , 2008, AIDS care.

[32]  R. Bodmeier,et al.  A novel in situ forming drug delivery system for controlled parenteral drug delivery. , 2007, International journal of pharmaceutics.

[33]  Kinam Park,et al.  In vitro and in vivo release of albumin using a biodegradable MPEG-PCL diblock copolymer as an in situ gel-forming carrier. , 2007, Biomacromolecules.

[34]  Mirja Andersson,et al.  Structural studies of poly(N‐isopropylacrylamide) microgels: Effect of SDS surfactant concentration in the microgel synthesis , 2006 .

[35]  Toshiyuki Shikata,et al.  Hydration and dynamic behavior of poly(N-isopropylacrylamide)s in aqueous solution: a sharp phase transition at the lower critical solution temperature. , 2006, Journal of the American Chemical Society.

[36]  R. Hjelm,et al.  Volume transition and internal structures of small poly(N‐isopropylacrylamide) microgels , 2005 .

[37]  J. Leroux,et al.  In situ-forming hydrogels--review of temperature-sensitive systems. , 2004, European journal of pharmaceutics and biopharmaceutics : official journal of Arbeitsgemeinschaft fur Pharmazeutische Verfahrenstechnik e.V.

[38]  T. Allègre,et al.  Therapeutic drug monitoring of lopinavir/ritonavir given alone or with a non-nucleoside reverse transcriptase inhibitor. , 2004, British journal of clinical pharmacology.

[39]  M. A. van de Laar,et al.  Bioavailability of higher dose methotrexate comparing oral and subcutaneous administration in patients with rheumatoid arthritis. , 2004, The Journal of rheumatology.

[40]  B. Vincent,et al.  Flocculation of microgel particles with sodium chloride and sodium polystyrene sulfonate as a function of temperature. , 2004, Langmuir : the ACS journal of surfaces and colloids.

[41]  Sanjay Garg,et al.  Factors affecting mechanism and kinetics of drug release from matrix-based oral controlled drug delivery systems , 2004 .

[42]  B. Vincent,et al.  Flocculation of microgel particles , 2004 .

[43]  H. Halkin,et al.  Bioavailability of oral vs. subcutaneous low‐dose methotrexate in patients with Crohn's disease , 2003, Alimentary pharmacology & therapeutics.

[44]  J. Cramer,et al.  A systematic review of the associations between dose regimens and medication compliance. , 2001, Clinical therapeutics.

[45]  W. Richtering,et al.  Influence of cross-link density on rheological properties of temperature-sensitive microgel suspensions , 2000 .

[46]  R. Pelton,et al.  Temperature-sensitive aqueous microgels. , 2000, Advances in colloid and interface science.

[47]  B. Vincent,et al.  Microgel particles as model colloids : theory, properties and applications , 1999 .

[48]  Xu Tongwen,et al.  Mechanism of sustained drug release in diffusion-controlled polymer matrix-application of percolation theory , 1998 .

[49]  R. Pelton,et al.  Poly(N-isopropylacrylamide) Latices Prepared with Sodium Dodecyl Sulfate , 1993 .

[50]  Nicholas A. Peppas,et al.  A simple equation for description of solute release I. Fickian and non-fickian release from non-swellable devices in the form of slabs, spheres, cylinders or discs , 1987 .

[51]  L. C. Graton,et al.  Systematic Packing of Spheres: With Particular Relation to Porosity and Permeability , 1935, The Journal of Geology.

[52]  D. Burgess,et al.  Long Acting Injections and Implants , 2012, Advances in Delivery Science and Technology.

[53]  P. Luckham,et al.  The rheology of deformable and thermoresponsive microgel particles , 1995 .

[54]  N. Peppas,et al.  Modelling of sustained release of water-soluble drugs from porous, hydrophobic polymers. , 1982, Biomaterials.