Cancer remains the one of the most common causes of mortality in humans; thus, cancer treatment is currently a major focus of investigation (1). Intense efforts aimed at improving conventional treatment did not achieve the desired goal and there has been little advancement on the overall cancer survival landscape. Chemotherapeutics used in cancer management have one prime purpose, which is eliminating malignant cells, a task usually achieved with high efficacy but little precision (2). Patients subjected to treatment paradigms with such non-specific toxic compounds commonly develop severe side effects that may be debilitating in their own right (3,4). Ehrlich introduced the concept of the ‘magic bullet’ at the turn of the 20th century (5). Since then, researchers worldwide have been searching for an optimal treatment that selectively targets cancer without afflicting significant morbidity. Recent advances in cancer nanotechnology have raised exciting opportunities for specific drug delivery by an emerging class of nanotherapeutics that may be targeted to neoplastic cells, thereby offering a major advantage over conventional chemotherapeutic agents (4,6). There are two ways by which targeting of nanoparticles may be achieved, namely passive and active targeting.

Passive targeting facilitates deposition of nanovectors within the tumor microenvironment, owing to distinctive characteristics inherent to the tumor milieu, not normally present in healthy tissues (5). The delivery of nanoparticles is determined by factors associated with the tumor microvasculature, in addition to factors inherent to the nanoparticle itself, such as size, shape and surface charge (5). Targeting strategies have taken a step further to enhance the selective uptake of nanoparticles into the tumor cells. Biorecognition molecules have been attached to the surface of the nanovectors to target specific markers that are overexpressed by the neoplastic cells. These strategies have been awarded the appellation ‘active targeting’, which exhibits a higher specificity and efficacy in achieving the desired goal (6). The aim of this study was to provide an overview of the factors orchestrated in the passive targeting of nanoparticles to tumors. In deference to the traditional views, we also aimed to investigate the various strategies that may be adopted to maximize the benefits of this approach.

In passive targeting, macromolecules including nanoparticles accumulate preferentially in the neoplastic tissues as a result of the enhanced permeability and retention (EPR) phenomenon, first described by Maeda and Matsumura (7,8). The EPR is based on the nanometer size range of the nanoparticles and two fundamental characteristics of the neoplastic tissues, namely, the leaky vasculature and impaired lymphatic drainage.

In 1986, Maeda et al (9) observed that intravenous administration of Evans blue dye, which binds to plasma albumin, resulted in selective concentration in tumor tissues. The tumor concentration of blue albumin mounted to ~10-fold that in the blood at 145 h. This phenomenon was also demonstrated with radio-labeled plasma proteins, including transferrin (90 kDa) and IgG (160 kDa), whereas smaller proteins, such as neocarzinostatin (12 kDa) and ovomucoid (29 kDa), did not accumulate within tumors (1,8,10). Subsequent studies have confirmed that macromolecules with a molecular weight above the renal threshold (40 kDa) tend to accumulate preferentially in neoplastic tissues upon intravenous administration (1,11). This unique phenomenon of preferential accumulation of macromolecules is the resultant effect of the abnormal vasculature and impaired lymphatic drainage within neoplastic tissues.

Once a malignant tumor grows to >2–3 mm³ in size, the delivery of oxygen and nutrients becomes diffusion-limited and the formation of new blood vessels becomes essential to meet the ever increasing demands of the rapidly growing malignant cells (3). This is accomplished through the release of angiogenic factors by the neoplastic tissue aiming to increase the microvasculature within the tumor in order to sustain further growth (3). The resultant imbalance of angiogenic factors and matrix metalloproteinases (MMPs) within neoplastic tissues results in highly disorganized vessels, which are dilated, with numerous pores and wide gap junctions between endothelial cells (12). The perivascular cells and basement membrane are absent or defective (1,13). Furthermore, tumor vessels frequently lack the smooth muscle layer that normally surrounds endothelial cells (14). The normal vasculature is endowed with tight junctions that are impermeable to molecules sized >2–4 nm, thus keeping the nanoparticles within the circulation; however, the leaky vasculature of neoplastic tissue allows macromolecules with a diameter of ≥600 nm to extravasate into the neoplastic tissues. Since tumors do not have a well-developed lymphatic system, these extravasated nanoparticles tend to stagnate within the neoplastic tissue (12,15). This phenomenon of leaky vasculature and impaired lymphatic drainage has been referred to as the EPR effect (7,8).

Nanoparticles may attain high concentrations within the neoplastic tissue via the EPR effect only if they are able to evade the reticuloendothelial system (RES) and resist renal clearance by virtue of their macromolecular size, thereby remaining in the circulation for ≥6 h (1).

With the rapid emergence of novel nanoparticulate devices, there comes a pressing need for greater precision in delivering drugs to neoplastic cancer cells, whilst salvaging the surrounding healthy tissues. The tumor microvasculature represents the epicenter of the concept of passive targeting of nanoparticles. Mediators regulating blood pressure and vascular caliber may be controlled to shift the balance towards a more inviting tumor environment for nanoparticles. Skeptics point to the fact that passive targeting facilitates the efficient localization of nanoparticles in the tumor interstitium, but cannot further promote their uptake by cancer cells. This uptake may be achieved by actively targeting nanoparticles to receptors overexpressed on target cancer cells. It is our view that the two strategies must be synchronized in order to achieve maximum benefit from future nanodesigned ‘magic bullets’.