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©2014 Baishideng Publishing Group Inc.
World J Gastroenterol. Oct 28, 2014; 20(40): 14717-14725
Published online Oct 28, 2014. doi: 10.3748/wjg.v20.i40.14717
Published online Oct 28, 2014. doi: 10.3748/wjg.v20.i40.14717
Table 1 Desired characteristics for a nanoparticle drug-delivery platform
| Desired characteristic | Comments |
| Inherently non-toxic materials and degradation products | The initial material selection should be based on non-toxic materials especially with an aim toward human health care |
| Small size (10–200 nm) | There is not a particular size that seems most efficacious, particularly based on in vivo studies. This is the range of particle diameters that have proven most effective for a wide variety of delivery systems. Also of note is the debate around the influence of particle shape[83] |
| Encapsulation of active agent | To be effective, the active agent must be encapsulated within the nanoparticle vehicle. Surface decoration (i.e., adsorption) will often be effective in vitro but falls short for in vivo studies because of the reticulum endoplasmic systems in vivo |
| Colloidally stable in physiological conditions | The nanoparticle vehicle and surface functionalization must resist agglomeration for the solution pH values, ionic strength, macromolecular interactions, and temperature encountered in the physiological environment |
| Clearance mechanism | The nanoparticle vehicle must have a ready clearance mechanism to avoid the cumulative and/or systemic effects of the drug-laden particles |
| Long clearance times | Resistance to agglomeration and other effects that remove the nanoparticle-encapsulated drug from the patient must be avoided to promote long circulation times in the circulatory system for as many of the nanoparticles to find and sequester in the cancer cells as possible |
| Biologically or extrinsically controlled release of therapeutic agents | There should be a trigger mechanism such as the acidic pH within the tumor or during endosome maturation designed into the nanoparticle platform to ensure the release of the encapsulated drug into the targeted tissue |
| Can be targeted to cell/tissue of choice | The nanoparticle platform should be capable of surface bioconjugation to target molecules for the specific cancer to provide the greatest uptake with the lesions and fewest least side effects with healthy tissue |
Table 2 The selection criteria for nanomaterial drug delivery systems
| Nano particulate material | Size (nm) | Therapeutic agent(s) carried | Advantages | Limitations |
| Biodegradable polymers | 10-100 | Plasmid DNA, proteins, peptides, low molecular-weight (MW) organic compounds | Sustained localized drug delivery for weeks | Exocytosis of undissolved nanoparticles. Fixed functionality after synthesis may require new synthetic pathways for alternate surface functionalities |
| Ceramic | < 100 | Proteins, DNA, chemotherapeutic agents, high MW organic compounds | Easily prepared, water dispersible, stable in biological environments | Toxicity of materials, exocytosis of undissolved nanoparticles, time consuming synthesis, surface decoration instead of encapsulation |
| Metals | < 50 | Proteins, DNA, chemotherapeutic agents | Small particles present a large surface area for surface decoration delivery | Toxicity of materials, exocytosis of undissolved nanoparticles, time consuming synthesis, surface decoration instead of encapsulation |
| Polymeric micelles | < 100 | Proteins, DNA, chemotherapeutic agents | Suitable for water-insoluble drugs due to hydrophobic core | Toxicity of materials, fixed functionality after synthesis |
| Dendrimers | < 10 | Chemotherapeutic agents, anti-bacterial, anti-viral agents, DNA, high MW organic compounds | Suitable for hydrophobic or hydrophilic drugs | May use toxic materials, time consuming synthesis, fixed functionality after synthesis may require new synthetic pathways for alternate surface functionalities |
| Liposomes | 50-100 | Chemotherapeutic agents, proteins, DNA | Reduced systemic toxicity, increased circulation time | Fixed functionality after synthesis, some leakage of encapsulated agent, lack of colloidal stability |
| 3D printing | 20-2000 | Chemotherapeutic agents, proteins, DNA, imaging agents | Precise control over size, shape, and surface functionalization. 3D printing can be used with an array of processing techniques to create porous scaffolds[85] and lab-on-chip devices[86] for personalized medicine[87] | Toxicity of materials depending on material |
| Calcium phosphosilicate | 20-60 | Chemotherapeutic agents, RNA, high and low MW organic compounds, imaging agents | Simple preparation, suitable for hydrophilic or hydrophobic drugs, colloidal stability in physiological environments, pH-dependent dissolution results in intracellular delivery of drugs, composed of bio-resorbable material | Encapsulated materials limited to solubility in water or organic solvent |
- Citation: Loc WS, Smith JP, Matters G, Kester M, Adair JH. Novel strategies for managing pancreatic cancer. World J Gastroenterol 2014; 20(40): 14717-14725
- URL: https://www.wjgnet.com/1007-9327/full/v20/i40/14717.htm
- DOI: https://dx.doi.org/10.3748/wjg.v20.i40.14717