Mechanoresponsive materials for drug delivery: Harnessing forces for controlled release☆

ABSTRACT Mechanically‐activated delivery systems harness existing physiological and/or externally‐applied forces to provide spatiotemporal control over the release of active agents. Current strategies to deliver therapeutic proteins and drugs use three types of mechanical stimuli: compression, tension, and shear. Based on the intended application, each stimulus requires specific material selection, in terms of substrate composition and size (e.g., macrostructured materials and nanomaterials), for optimal in vitro and in vivo performance. For example, compressive systems typically utilize hydrogels or elastomeric substrates that respond to and withstand cyclic compressive loading, whereas, tension‐responsive systems use composites to compartmentalize payloads. Finally, shear‐activated systems are based on nanoassemblies or microaggregates that respond to physiological or externally‐applied shear stresses. In order to provide a comprehensive assessment of current research on mechanoresponsive drug delivery, the mechanical stimuli intrinsically present in the human body are first discussed, along with the mechanical forces typically applied during medical device interventions, followed by in‐depth descriptions of compression, tension, and shear‐mediated drug delivery devices. We conclude by summarizing the progress of current research aimed at integrating mechanoresponsive elements within these devices, identifying additional clinical opportunities for mechanically‐activated systems, and discussing future prospects. Graphical abstract Figure. No Caption available.

[1]  G. Husseini,et al.  The use of ultrasound to release chemotherapeutic drugs from micelles and liposomes , 2015, Journal of drug targeting.

[2]  Murat Guvendiren,et al.  Shear-thinning hydrogels for biomedical applications , 2012 .

[3]  M. C. Stuart,et al.  Emerging applications of stimuli-responsive polymer materials. , 2010, Nature materials.

[4]  Xuanhe Zhao,et al.  Cephalopod-inspired design of electro-mechano-chemically responsive elastomers for on-demand fluorescent patterning , 2014, Nature Communications.

[5]  Christy K. Holland,et al.  Ultrasound-Mediated Drug Delivery for Cardiovascular Disease , 2017 .

[6]  Kostas Kostarelos,et al.  Design, engineering and structural integrity of electro-responsive carbon nanotube- based hydrogels for pulsatile drug release. , 2013, Journal of materials chemistry. B.

[7]  Riaz Agha,et al.  A review of the role of mechanical forces in cutaneous wound healing. , 2011, The Journal of surgical research.

[8]  Victor Frenkel,et al.  Ultrasound mediated delivery of drugs and genes to solid tumors. , 2008, Advanced drug delivery reviews.

[9]  Jun Ge,et al.  Controlled display of enzyme activity with a stretchable hydrogel. , 2013, Chemical communications.

[10]  Zhen Gu,et al.  Mechanical Force-Triggered Drug Delivery. , 2016, Chemical reviews.

[11]  S. Murdan Electro-responsive drug delivery from hydrogels. , 2003, Journal of controlled release : official journal of the Controlled Release Society.

[12]  D. Ingber Tensegrity II. How structural networks influence cellular information processing networks , 2003, Journal of Cell Science.

[13]  Wei-Min Ren,et al.  Stimuli-responsive polymers for anti-cancer drug delivery. , 2014, Materials science & engineering. C, Materials for biological applications.

[14]  K. Hata,et al.  A stretchable carbon nanotube strain sensor for human-motion detection. , 2011, Nature nanotechnology.

[15]  Zhixiang Tong,et al.  Hyaluronic acid-based hydrogels containing covalently integrated drug depots: implication for controlling inflammation in mechanically stressed tissues. , 2013, Biomacromolecules.

[16]  Y. Bae,et al.  Electrically credible polymer gel for controlled release of drugs , 1991, Nature.

[17]  Kwanwoo Shin,et al.  Mechanical stimuli responsive and highly elastic biopolymer/nanoparticle hybrid microcapsules for controlled release. , 2016, Journal of materials chemistry. B.

[18]  Carmen Alvarez-Lorenzo,et al.  Light‐sensitive Intelligent Drug Delivery Systems † , 2009, Photochemistry and photobiology.

[19]  K. Matyjaszewski,et al.  The development of microgels/nanogels for drug delivery applications , 2008 .

[20]  Bror Svarfvar,et al.  Drug Release from pH and Ionic Strength Responsive Poly(acrylic acid) Grafted Poly(vinylidenefluoride) Membrane Bags In Vitro , 2004, Pharmaceutical Research.

[21]  Xiaoying Lu,et al.  Reversible Superhydrophobicity to Superhydrophilicity Transition by Extending and Unloading an Elastic Polyamide Film , 2005 .

[22]  D. Mooney,et al.  Hydrogels for tissue engineering: scaffold design variables and applications. , 2003, Biomaterials.

[23]  Eleanor Stride,et al.  Magnetic targeting and ultrasound mediated drug delivery: Benefits, limitations and combination , 2012, International journal of hyperthermia : the official journal of European Society for Hyperthermic Oncology, North American Hyperthermia Group.

[24]  S T Quek,et al.  Mechanical models for living cells--a review. , 2006, Journal of biomechanics.

[25]  Donald E Ingber,et al.  Targeted drug delivery to flow-obstructed blood vessels using mechanically activated nanotherapeutics. , 2015, JAMA neurology.

[26]  Nina S Sverdlova,et al.  Principles of determination and verification of muscle forces in the human musculoskeletal system: Muscle forces to minimise bending stress. , 2010, Journal of biomechanics.

[27]  Julio César Cuggino,et al.  Stimulus-responsive nanogels for drug delivery , 2018 .

[28]  Joseph Hemmerlé,et al.  Layer-by-Layer Enzymatic Platform for Stretched-Induced Reactive Release , 2012 .

[29]  D. Ingber,et al.  Shear-Activated Nanotherapeutics for Drug Targeting to Obstructed Blood Vessels , 2012, Science.

[30]  Donald E Ingber,et al.  Mechanobiology and diseases of mechanotransduction , 2003, Annals of medicine.

[31]  Walter Herzog,et al.  Model-based estimation of muscle forces exerted during movements. , 2007, Clinical biomechanics.

[32]  A. Khademhosseini,et al.  Hydrogels in Biology and Medicine: From Molecular Principles to Bionanotechnology , 2006 .

[33]  Yolonda L Colson,et al.  Superhydrophobic materials for biomedical applications. , 2016, Biomaterials.

[34]  Joseph Kost,et al.  Ultrasound mediated transdermal drug delivery. , 2014, Advanced drug delivery reviews.

[35]  Yolonda L Colson,et al.  Biologically Responsive Polymeric Nanoparticles for Drug Delivery , 2012, Advanced materials.

[36]  P. Prendergast,et al.  Cardiovascular stent design and vessel stresses: a finite element analysis. , 2005, Journal of biomechanics.

[37]  Sadik Esener,et al.  Ultrasound mediated localized drug delivery. , 2012, Advances in experimental medicine and biology.

[38]  Mark W. Grinstaff,et al.  Self-assembled nanofiber hydrogels for mechanoresponsive therapeutic anti-TNFα antibody delivery. , 2016, Chemical communications.

[39]  Quanguo He,et al.  A Nanoscale System for Remarkably Enhanced Drug Delivery Based on Hollow Magnetic Particles Encapsulated Within Temperature-Responsive Poly(methylmethacrylate) , 2014 .

[40]  B. Müller,et al.  Shear-stress sensitive lenticular vesicles for targeted drug delivery. , 2012, Nature nanotechnology.

[41]  J. Lyszczarz,et al.  [Mechanical properties of the lungs]. , 1971, Acta physiologica Polonica.

[42]  P ? ? ? ? ? ? ? % ? ? ? ? , 1991 .

[43]  Ivan P Parkin,et al.  Preparation and characterisation of super-hydrophobic surfaces. , 2010, Chemistry.

[44]  Helmuth Möhwald,et al.  LbL Films as Reservoirs for Bioactive Molecules , 2010 .

[45]  Antoine Ferreira,et al.  Optimal structure of particles-based superparamagnetic microrobots: application to MRI guided targeted drug therapy , 2015, Journal of Nanoparticle Research.

[46]  Unyong Jeong,et al.  A Strain‐Regulated, Refillable Elastic Patch for Controlled Release , 2016 .

[47]  Jeffrey A Goldstein,et al.  Comparison of the diameter consistency and dilating force of the controlled radial expansion balloon catheter to the conventional balloon dilators , 2000, American Journal of Gastroenterology.

[48]  Younan Xia,et al.  Strain-controlled release of molecules from arrayed microcapsules supported on an elastomer substrate. , 2011, Angewandte Chemie.

[49]  Zhiyong Tang,et al.  Biomedical Applications of Layer‐by‐Layer Assembly: From Biomimetics to Tissue Engineering , 2006 .

[50]  M Zamir,et al.  Shear forces and blood vessel radii in the cardiovascular system , 1977, The Journal of general physiology.

[51]  Patrick Couvreur,et al.  Stimuli-responsive nanocarriers for drug delivery. , 2013, Nature materials.

[52]  Jim Euchner Design , 2014, Catalysis from A to Z.

[53]  Samir Mitragotri,et al.  Platelet-like Nanoparticles: Mimicking Shape, Flexibility, and Surface Biology of Platelets To Target Vascular Injuries , 2014, ACS nano.

[54]  A. Tencer,et al.  Effects of cyclical mechanical stress on the controlled release of proteins from a biodegradable polymer implant. , 1997, Journal of biomedical materials research.

[55]  Theo Arts,et al.  Wall Shear Stress – an Important Determinant of Endothelial Cell Function and Structure – in the Arterial System in vivo , 2006, Journal of Vascular Research.

[56]  N. Peppas,et al.  Hydrogels in Pharmaceutical Formulations , 1999 .

[57]  G. Laurent,et al.  Mechanisms of tissue repair: from wound healing to fibrosis. , 1997, The international journal of biochemistry & cell biology.

[58]  Katsuhiko Ariga,et al.  β-Cyclodextrin-crosslinked alginate gel for patient-controlled drug delivery systems: regulation of host-guest interactions with mechanical stimuli. , 2013, Journal of materials chemistry. B.

[59]  Mark Borden,et al.  State-of-the-art materials for ultrasound-triggered drug delivery. , 2014, Advanced drug delivery reviews.

[60]  Na Li,et al.  Temperature-responsive DNA-gated nanocarriers for intracellular controlled release. , 2014, Chemical communications.

[61]  Mitsuru Hashida,et al.  Ultrasound induced cancer immunotherapy. , 2014, Advanced drug delivery reviews.

[62]  Jeong-Woo Choi,et al.  Polyelectrolyte multilayer microcapsules: Self-assembly and toward biomedical applications , 2007 .

[63]  Guanghui Ma,et al.  Co-Assembly of Heparin and Polypeptide Hybrid Nanoparticles for Biomimetic Delivery and Anti-Thrombus Therapy. , 2016, Small.

[64]  C. Kumar,et al.  Magnetic nanomaterials for hyperthermia-based therapy and controlled drug delivery. , 2011, Advanced drug delivery reviews.

[65]  David J. Mooney,et al.  Controlled growth factor release from synthetic extracellular matrices , 2000, Nature.

[66]  Samir Mitragotri,et al.  Platelet-like Nanoparticles (PLNs): Engineering Shape, Flexibility and Surface Chemistry of Nanocarriers to Target Vascular Injuries , 2014 .

[67]  Stéphane G Carlier,et al.  Intravascular ultrasound assessment of drug-eluting stent expansion. , 2007, American heart journal.

[68]  Young Moo Lee,et al.  Drug release behavior of electrical responsive poly(vinyl alcohol)/poly(acrylic acid) IPN hydrogels under an electric stimulus , 1999 .

[69]  Paul M. George,et al.  Electrically Controlled Drug Delivery from Biotin‐Doped Conductive Polypyrrole , 2006 .

[70]  Uday B Kompella,et al.  Ophthalmic light sensitive nanocarrier systems. , 2008, Drug discovery today.

[71]  Irina Popescu,et al.  Poly(N-isopropylacrylamide-co-methacrylic acid) pH/thermo-responsive porous hydrogels as self-regulated drug delivery system. , 2014, European journal of pharmaceutical sciences : official journal of the European Federation for Pharmaceutical Sciences.

[72]  Adrian Bowyer,et al.  A novel pH- and ionic-strength-sensitive carboxy methyl dextran hydrogel. , 2005, Biomaterials.

[73]  David H. Thompson,et al.  Phototriggering of liposomal drug delivery systems. , 2001, Advanced drug delivery reviews.

[74]  Vladimir P. Torchilin,et al.  Targeted Drug Delivery Systems: Strategies and Challenges , 2015 .

[75]  Joseph Hemmerlé,et al.  Mechanotransductive surfaces for reversible biocatalysis activation. , 2009, Nature materials.

[76]  Bappaditya Chatterjee,et al.  pH responsive polymers in drug delivery , 2018 .

[77]  D C Harrison,et al.  A new catheter system for coronary angioplasty. , 1982, The American journal of cardiology.

[78]  Sanlin S. Robinson,et al.  Highly stretchable electroluminescent skin for optical signaling and tactile sensing , 2016, Science.

[79]  T. Okano,et al.  Thermo-responsive drug delivery from polymeric micelles constructed using block copolymers of poly(N-isopropylacrylamide) and poly(butylmethacrylate). , 1999, Journal of controlled release : official journal of the Controlled Release Society.

[81]  Joseph Hemmerlé,et al.  Mechanically responding nanovalves based on polyelectrolyte multilayers. , 2007, Nano letters.

[82]  John B. Shoven,et al.  I , Edinburgh Medical and Surgical Journal.

[83]  P. Hammond Form and Function in Multilayer Assembly: New Applications at the Nanoscale , 2004 .

[84]  Sanyog Jain,et al.  Targeted Drug Delivery : Concepts and Design , 2015, Advances in Delivery Science and Technology.

[85]  Jun Ge,et al.  Drug release from electric-field-responsive nanoparticles. , 2012, ACS nano.

[86]  D. Schmaljohann Thermo- and pH-responsive polymers in drug delivery. , 2006, Advanced drug delivery reviews.

[87]  Kinam Park,et al.  Environment-sensitive hydrogels for drug delivery , 2001 .

[88]  A. Klibanov,et al.  Nucleic acid delivery with microbubbles and ultrasound. , 2014, Advanced drug delivery reviews.

[89]  Andrew J Boydston,et al.  Successive mechanochemical activation and small molecule release in an elastomeric material. , 2014, Journal of the American Chemical Society.

[90]  Yahya E Choonara,et al.  A review of integrating electroactive polymers as responsive systems for specialized drug delivery applications. , 2014, Journal of Biomedical Materials Research. Part A.

[91]  Jeffrey A. Hubbell,et al.  Photopolymerized hydrogel materials for drug delivery applications , 1995 .

[92]  A. Hoffman Hydrogels for Biomedical Applications , 2001, Advanced drug delivery reviews.

[93]  K. Salaita,et al.  Visualizing mechanical tension across membrane receptors with a fluorescent sensor , 2011, Nature Methods.

[94]  Samir Mitragotri,et al.  Healing sound: the use of ultrasound in drug delivery and other therapeutic applications , 2005, Nature Reviews Drug Discovery.

[95]  Jie Chen,et al.  pH-responsive drug delivery systems based on clickable poly(L-glutamic acid)-grafted comb copolymers , 2012, Macromolecular Research.

[96]  P. Calvert Hydrogels for Soft Machines , 2009 .

[97]  D. Mooney,et al.  Alginate: properties and biomedical applications. , 2012, Progress in polymer science.

[98]  Ali Khademhosseini,et al.  Magnetically Responsive Polymeric Microparticles for Oral Delivery of Protein Drugs , 2005, Pharmaceutical Research.

[99]  F. Hirayama,et al.  Cyclodextrin-based controlled drug release system. , 1999, Advanced drug delivery reviews.

[100]  David J. Mooney,et al.  Controlled Drug Delivery from Polymers by Mechanical Signals , 2001 .

[101]  Yolonda L Colson,et al.  Expansile nanoparticles: synthesis, characterization, and in vivo efficacy of an acid-responsive polymeric drug delivery system. , 2009, Journal of the American Chemical Society.

[102]  Philippe Lavalle,et al.  Stretch-induced biodegradation of polyelectrolyte multilayer films for drug release. , 2012, Langmuir : the ACS journal of surfaces and colloids.

[103]  Fabian Kiessling,et al.  Recent advances in molecular, multimodal and theranostic ultrasound imaging. , 2014, Advanced drug delivery reviews.

[104]  M. Yoshimoto,et al.  Mechanosensitive liposomes as artificial chaperones for shear-driven acceleration of enzyme-catalyzed reaction. , 2014, ACS applied materials & interfaces.

[105]  D. Mooney,et al.  Hydrogels for tissue engineering. , 2001, Chemical reviews.

[106]  Zhen Gu,et al.  Stretch-Triggered Drug Delivery from Wearable Elastomer Films Containing Therapeutic Depots. , 2015, ACS nano.

[107]  Laura Curiel,et al.  High intensity focused ultrasound technology, its scope and applications in therapy and drug delivery. , 2014, Journal of pharmacy & pharmaceutical sciences : a publication of the Canadian Society for Pharmaceutical Sciences, Societe canadienne des sciences pharmaceutiques.

[108]  P. Grayburn,et al.  Cardiovascular drug delivery with ultrasound and microbubbles. , 2014, Advanced drug delivery reviews.

[109]  Gareth H. McKinley,et al.  Fabrics with Tunable Oleophobicity , 2009 .

[110]  G L Amidon,et al.  A pH- and ionic strength-responsive polypeptide hydrogel: synthesis, characterization, and preliminary protein release studies. , 1999, Journal of biomedical materials research.

[111]  Weiqiang Wang,et al.  Stent expansion in curved vessel and their interactions: a finite element analysis. , 2007, Journal of biomechanics.

[112]  S. Van Vlierberghe,et al.  Biopolymer-based hydrogels as scaffolds for tissue engineering applications: a review. , 2011, Biomacromolecules.

[113]  Kazuaki Ninomiya,et al.  Ultrasound-mediated drug delivery using liposomes modified with a thermosensitive polymer. , 2014, Ultrasonics sonochemistry.

[114]  Jong-Bum Seo High Intensity Focused Ultrasound for Cancer Treatment: Current Agenda and the Latest Technology Trends , 2010 .

[115]  M. Dewhirst,et al.  The development and testing of a new temperature-sensitive drug delivery system for the treatment of solid tumors. , 2001, Advanced drug delivery reviews.

[116]  Sigurd Wagner,et al.  Electronic skin: architecture and components , 2004 .

[117]  U. Häfeli,et al.  Magnetically modulated therapeutic systems. , 2004, International journal of pharmaceutics.

[118]  Wim E Hennink,et al.  Hydrogels for protein delivery. , 2012, Chemical reviews.

[119]  Jiahua Zhu,et al.  Mechano-Responsive Hydrogels Crosslinked by Block Copolymer Micelles. , 2012, Soft matter.

[120]  Hui Gao,et al.  Temperature-responsive drug delivery systems based on polyaspartamides with isopropylamine pendant groups , 2013 .

[121]  Wouter Olthuis,et al.  Hydrogel-based devices for biomedical applications , 2010 .

[122]  P. Gupta,et al.  Hydrogels: from controlled release to pH-responsive drug delivery. , 2002, Drug discovery today.

[123]  Yanzhong Zhang,et al.  Regulating drug release from pH- and temperature-responsive electrospun CTS-g-PNIPAAm/poly(ethylene oxide) hydrogel nanofibers , 2014, Biomedical materials.

[124]  Yang Liu,et al.  Synthesis and characterization of β-cyclodextrin-conjugated alginate hydrogel for controlled release of hydrocortisone acetate in response to mechanical stimulation , 2015 .

[125]  F. Auricchio,et al.  Mechanical behavior of coronary stents investigated through the finite element method. , 2002, Journal of biomechanics.

[126]  Charles Maynard,et al.  Trends in Coronary Revascularization in the United States From 2001 to 2009: Recent Declines in Percutaneous Coronary Intervention Volumes , 2011, Circulation. Cardiovascular quality and outcomes.

[127]  Yubo Fan,et al.  Controlled release of BSA by microsphere-incorporated PLGA scaffolds under cyclic loading , 2011 .

[128]  Ron,et al.  Temperature-responsive gels and thermogelling polymer matrices for protein and peptide delivery. , 1998, Advanced drug delivery reviews.

[129]  Gerardo F. Goya,et al.  An integrated device for magnetically-driven drug release and in situ quantitative measurements: Design, fabrication and testing , 2015 .

[130]  Yonggang Huang,et al.  Materials and Mechanics for Stretchable Electronics , 2010, Science.

[131]  Wouter Olthuis,et al.  Stimulus-sensitive hydrogels and their applications in chemical (micro)analysis. , 2003, The Analyst.

[132]  P Y Wang,et al.  Implantable reservoir for supplemental insulin delivery on demand by external compression. , 1989, Biomaterials.

[133]  Jonah A Kaplan,et al.  Stretch-Induced Drug Delivery from Superhydrophobic Polymer Composites: Use of Crack Propagation Failure Modes for Controlling Release Rates. , 2016, Angewandte Chemie.

[134]  B. Müller,et al.  The use of shear stress for targeted drug delivery. , 2013, Cardiovascular research.

[135]  Z. Suo,et al.  Highly stretchable and tough hydrogels , 2012, Nature.

[136]  Nikos Boukos,et al.  Development of multiple stimuli responsive magnetic polymer nanocontainers as efficient drug delivery systems. , 2014, Macromolecular bioscience.

[137]  Hyun Chul Lee,et al.  Remission in models of type 1 diabetes by gene therapy using a single-chain insulin analogue , 2000, Nature.

[138]  Nathan McDannold,et al.  Ultrasound-mediated blood-brain barrier disruption for targeted drug delivery in the central nervous system , 2014, Defense + Security Symposium.

[139]  G. G. Stokes "J." , 1890, The New Yale Book of Quotations.

[140]  Chen Jiang,et al.  pH-sensitive drug-delivery systems for tumor targeting. , 2013, Therapeutic delivery.

[141]  D. Ku,et al.  Hemodynamics and atherosclerosis. Insights and perspectives gained from studies of human arteries. , 1988, Archives of pathology & laboratory medicine.

[142]  Hua Xiong,et al.  Thermally and Magnetically Dual- Responsive Mesoporous Silica Nanospheres: Preparation, Characterization, and Properties for the Controlled Release of Sophoridine , 2014 .

[143]  Holger Grüll,et al.  Magnetic resonance guided high-intensity focused ultrasound for image-guided temperature-induced drug delivery. , 2014, Advanced drug delivery reviews.

[144]  R V Kulkarni,et al.  Electrically responsive smart hydrogels in drug delivery: a review. , 2008, Journal of applied biomaterials & biomechanics : JABB.

[145]  D. Mooney,et al.  Hydrogels for tissue engineering. , 2001, Chemical Reviews.

[146]  C. Martin 2015 , 2015, Les 25 ans de l’OMC: Une rétrospective en photos.

[147]  D. Ingber,et al.  Shear-Activated Nanoparticle Aggregates Combined With Temporary Endovascular Bypass to Treat Large Vessel Occlusion , 2015, Stroke.

[148]  Martin A. Schwartz,et al.  The Force Is with Us , 2009, Science.

[149]  Siowling Soh,et al.  Stimuli‐Responsive Surfaces for Tunable and Reversible Control of Wettability , 2015, Advanced materials.

[150]  Scott D Fitzpatrick,et al.  Temperature-sensitive polymers for drug delivery , 2012, Expert review of medical devices.

[151]  Jeffrey I Zink,et al.  Light-activated nanoimpeller-controlled drug release in cancer cells. , 2008, Small.

[152]  Emanuele Luigi Carniel,et al.  A REVIEW OF THE EFFECTS OF BODY TEMPERATURE VARIATIONS ON RESPIRATORY MECHANICS: MEASUREMENTS BY THE END-INFLATION OCCLUSION METHOD IN THE RAT , 2015 .

[153]  Gareth H. McKinley,et al.  Designing Superoleophobic Surfaces , 2007, Science.

[154]  Yi Cui,et al.  Stretchable, porous, and conductive energy textiles. , 2010, Nano letters.

[155]  D. Kohane,et al.  HYDROGELS IN DRUG DELIVERY: PROGRESS AND CHALLENGES , 2008 .

[156]  Mizuo Maeda,et al.  pH-responsive release of proteins from biocompatible and biodegradable reverse polymer micelles. , 2014, Journal of controlled release : official journal of the Controlled Release Society.

[157]  T. Murakami,et al.  Targeted delivery of anticancer drugs with intravenously administered magnetic liposomes in osteosarcoma-bearing hamsters. , 2000, International journal of oncology.

[158]  Xi Zhang,et al.  Superhydrophobic surfaces: from structural control to functional application , 2008 .

[159]  Robert Langer,et al.  Near-infrared–actuated devices for remotely controlled drug delivery , 2014, Proceedings of the National Academy of Sciences.

[160]  Omid C Farokhzad,et al.  pH-Responsive nanoparticles for drug delivery. , 2010, Molecular pharmaceutics.

[161]  Jason Castle,et al.  Ultrasound-mediated targeted drug delivery: recent success and remaining challenges. , 2013, American journal of physiology. Heart and circulatory physiology.

[162]  J. Hubbell,et al.  Synthetic biomaterials as instructive extracellular microenvironments for morphogenesis in tissue engineering , 2005, Nature Biotechnology.

[163]  Robert Langer,et al.  A magnetically triggered composite membrane for on-demand drug delivery. , 2009, Nano letters.

[164]  Xing-Jie Liang,et al.  pH-sensitive nano-systems for drug delivery in cancer therapy. , 2014, Biotechnology advances.