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Expert Opinion on Drug Delivery Volume 7, 2010 - Issue 4
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Reviews

Designer nanoparticles: incorporating size, shape and triggered release into nanoscale drug carriers

Mary Caldorera-Moore The University of Texas at Austin, Department of Biomedical Engineering, 1 University Station, C0800, Austin, TX 78712-0238, USA
, MS,
Nathalie Guimard The University of Texas at Austin, Department of Biomedical Engineering, 1 University Station, C0800, Austin, TX 78712-0238, USA
, PhD,
Li Shi The University of Texas at Austin, Department of Mechanical Engineering, 1 University Station, C0800, Austin, TX 78712-0238, USA
, PhD &
Krishnendu Roy General Dynamics Endowed Faculty Fellow, Associate Professor and Graduate Advisor, The University of Texas at Austin, BME 5.202B, C0800, 1 University Station, Austin, TX 78712-1062, USA +1 512 232 3477; +1 512 471 0616; [email protected]
, PhD
Pages 479-495 | Published online: 23 Mar 2010
 
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Abstract

Importance of the field: Although significant progress has been made in delivering therapeutic agents through micro and nanocarriers, precise control over in vivo biodistribution and disease-responsive drug release has been difficult to achieve. This is critical for the success of next generation drug delivery devices, as newer drugs, designed to interfere with cellular functions, must be efficiently and specifically delivered to diseased cells. The chief constraint in achieving this has been our limited repertoire of particle synthesis methods, especially at the nanoscale. Recent developments in generating shape-specific nanocarriers and the potential to combine stimuli-responsive release with nanoscale delivery devices show great promise in overcoming these limitations.

Areas covered in this review: How recent advances in fabrication technology allow synthesis of highly monodisperse, stimuli-responsive, drug-carrying nanoparticles of precise geometries is discussed. How particle properties, specifically shape and stimuli responsiveness, affect biodistribution, cellular uptake and drug release is also reviewed.

What the reader will gain: The reader is introduced to recent developments in intelligent drug nanocarriers and new nanofabrication approaches that can be combined with disease-responsive biomaterials. This will provide insight into the importance of controlling particle geometry and incorporating stimuli-responsive materials into drug delivery.

Take home message: The integration of responsive biomaterials into shape-specific nanocarriers is one of the most promising avenues towards the development of next generation, advanced drug delivery systems.

Acknowledgments

The authors acknowledge partial funding from the National Science Foundation and the National Institutes of Health for their work on shape-specific nanoparticles.

Notes

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