Imaging Nanomedicine-Based Drug Delivery: a Review of Clinical Studies

Drug delivery systems based on nanoparticle technologies have been explored for more than 40 years, being one of the most active multidisciplinary fields of research to date [1]. Of the several drug delivery platforms available, liposomes, polymers, and solid inorganic nanoparticles have been the most widely studied. The rationale behind these drug carrier systems is to exploit their specific pharmacokinetic and biodistribution properties to deliver sufficient therapeutic amounts of the drug cargo to the specific target(s) (the drug being usually a toxic and/or insoluble small molecule), and to reduce its side effects due to local controlled release. To date, several nanomedicine drug delivery systems based on these concepts have been translated into clinical products, these include Abraxane®, DaunoXome®, Doxil®/Caelyx®, Marqibo®, Myocet®, and Onivyde® among others, with more in clinical trials (> 45 found in ClinicalTrials.​gov).

Imaging has played a very important role in the progress of this field. From a developmental perspective, it allows the non-invasive measurement of the biodistribution and pharmacokinetics of these drug delivery systems in animal models of disease, allowing us to select the best candidates by providing answers to important questions such as “Where do they go inside the body?,” “How long do they stay?,” “How are they cleared?,” “Are they reaching the target? and if so, how much?,” and “Is the drug being released?.” Several imaging techniques are available to obtain such information. To gain a deeper understanding of the different preclinical imaging modalities available—with their intrinsic advantages and disadvantages—and how they have supported the preclinical development of drug delivery systems—we refer the reader to several recent reviews on this area [2‐7].

In the clinical setting, imaging can play an additional role due to human and disease heterogeneity. It is widely accepted that human/disease heterogeneity affects the efficacy of all therapies and is particularly detrimental to the clinical effectiveness and translation of therapeutic nanomedicines [8‐10]. Unlike in animal models of disease, where most frequently the same genetic strains of mice and disease cell lines are used to assess the efficacy of drug delivery systems, in humans, heterogeneity is present between patients with different diseases, those with the same disease, and even within different lesions of the same patient. This heterogeneity has led to nanomedicines being approved based on their improved safety profile compared to conventional drugs, rather than improvements in therapeutic efficacy [11]. Hence, to overcome this problem, imaging methods that allow us to predict at the patient-to-patient level the efficacy of drug delivery systems, as well other therapeutics, could play important roles in the future [9].

The objective of this review is to analyze the progress and future prospects in the area of imaging drug delivery in humans. Our aim is twofold: first, we want to provide a descriptive analysis to date on how different clinical imaging techniques have played an important role in providing proof-of-concept data to support the development of drug delivery systems into clinical products. Second, we aim at highlighting how recent studies are shining new light into the inter- and intra-patient heterogeneity problem and how imaging can be used to predict drug delivery/therapeutic efficacy. Where possible, we have also tried to highlight findings from all of these studies that, in our opinion, deserve further attention.

To identify clinical studies in the field of image-guided drug delivery, we searched PubMed in January 2018, using combinations of the following terms: drug delivery, imaging, liposome, MRI, nanomedicine, nanoparticle, PET, radiolabeled, scintigraphy, SPECT, and ultrasound. Results were then restricted to clinical trials and articles were manually screened for relevance (Table 1). Studies in which imaging, most frequently x-ray computed tomography (CT) and 2-deoxy-2-[¹⁸F]fluoro-d-glucose (FDG) positron emission tomography (PET), was used solely for monitoring response to treatment were not included. With the focus being on nanomedicine drug delivery systems, studies of labeled small molecules and antibodies were not considered. For a brief overview of antibody-based theranostics, we refer the reader to the excellent review by Moek et al. [32]. The results of our search showed that liposome technologies are the most studied drug delivery system in humans. For reviews on image-guided drug delivery focused more specifically on clinical applications of liposomes in combination with imaging, we refer the reader to recently published reviews by Petersen et al. [33] and Lamichhane et al. [34]. Our search results also highlighted that the majority of the clinical studies of imaging-guided drug delivery to date have been performed using nuclear imaging modalities, principally planar gamma scintigraphy with only a minority using single-photon emission computed tomography (SPECT) or PET. This was followed by fewer studies using ultrasound (US) and magnetic resonance imaging (MRI). A brief description of each imaging technique is provided in each section, and the reader will find an excellent overview and comparison of the various imaging techniques in the introduction to molecular imaging by James and Gambhir [35]. All results have been organized in two levels, imaging technique and disease.

Gamma scintigraphy and single-photon emission computed tomography (SPECT) imaging rely on gamma-emitting radioisotopes, most commonly technetium-99m (^99mTc, t_1/2 = 6.0 h, γ = 140 keV), indium-111 (¹¹¹In, t_1/2 = 2.8 day, γ = 171 keV, 245 keV), iodine-123 (¹²³I, t_1/2 = 13.2 h, γ = 159 keV), or iodine-131 (¹³¹I, t_1/2 = 8.0 day, γ = 364 keV) in the clinic. The signal is captured by a gamma camera, equipped with collimators to localize the origin of the signal. Conventional scintigraphy provides two-dimensional (2D) images. In SPECT imaging, the gamma camera is rotated around the patient to obtain multiple 2D projections which can then be reconstructed into a three-dimensional (3D) image. Current clinical SPECT scanners provide a spatial resolution of 8–10 mm, a temporal resolution of a few minutes and a sensitivity of 10⁻¹⁰ to 10⁻¹¹ mol/l of radiotracer [35].

The most commonly used positron-emitting radionuclides in clinical studies are fluorine-18 (F-18, t_1/2 = 110 min), rubidium-82 (Rb-82, t_1/2 = 1.3 min), carbon-11 (C-11, t_1/2 = 20.3 min), gallium-68 (Ga-68, t_1/2 = 67.8 min), copper-64 (Cu-64, t_1/2 = 12.7 h), and zirconium-89 (Zr-89, t_1/2 = 3.27 day). Positrons emitted from PET radioisotopes travel up to a short distance (positron range, up to a few mm) before encountering an electron, at which point an annihilation event produces two 511-keV gamma rays at a near 180° angle. This pair of coincident gamma photons is detected by the PET camera, in which detectors are arranged in several static rings, providing 3D images. The coincidence detection allows to dispense with physical collimators used in SPECT/planar scintigraphy, thereby increasing the sensitivity of PET scanners by several orders of magnitude over SPECT scanners, in the range of 10⁻¹¹ to 10⁻¹² mol/l of radiotracer, as well as the temporal resolution [35]. The lack of collimators also results in signals that are more easily quantifiable than those from gamma-emitting isotopes, and a maximum spatial resolution of approximately 5 mm. Despite these advantages, only two recent clinical studies of nanomedicines using PET have had results published as of April 2018, both in the field of oncology.

In the context of a clinical trial (NCT01304797) of MM-302, a formulation of PEGylated liposomal doxorubicin targeted against human epidermal growth factor receptor 2 (HER2), Lee et al. [28] selected 19 patients with metastatic breast cancer for an imaging study using MM-302 radiolabeled with Cu-64. Current clinically approved formulations of PEGylated liposomal doxorubicin (Doxil®/Caelyx®, Myocet®) do not possess targeting moieties and rely solely in the EPR effect. MM-302 is targeted towards HER-2 with the objective of increasing delivery of doxorubicin in HER2-overexpressing cells rather than in macrophages, as observed in a preclinical study [45].

The authors sought to determine whether the amount of drug reaching the metastases would correlate with therapeutic efficacy. Treatment with MM-302 was given along with trastuzumab (a clinically approved anti-HER2 monoclonal antibody). The chelating and loading agent 4-DEAP-ATSC [46] was used to radiolabel MM-302 with Cu-64, with a target dose of 400 MBq per patient. The maximum Cu-64 activity remaining in the patients would be 108 MBq after 24 h and 29 MBq after 48 h, potentially sufficient for PET imaging at this time point. Results from PET imaging (Fig. 3) showed that [⁶⁴Cu]MM-302 remained in the circulation for over 24 h, and thereafter accumulated mostly in the liver and spleen, in good agreement with preclinical data.

The authors state that free Cu-64 was not detectable in the patients selected for more detailed analysis. This is not surprising, because free Cu-64 has high affinity for liver and spleen tissues and rapidly accumulates in these organs [47]. Therefore, assessing the stability of the Cu-64 radiolabeling of MM-302 based on PET images is not straightforward. Based on preclinical data showing that the biodistribution of MM-302 could be affected by treatment with cyclophosphamide, the patients selected for the imaging study were taken both from a group receiving MM-302 and trastuzumab and from a group receiving cyclophosphamide in addition. However, no differences in drug uptake were observed between these two groups, leading the patients to be analyzed as a single group for the rest of the study. There were several important results from the study. The first is the large heterogeneity in drug uptake not only between subjects but also between lesions within subjects. This high variability of the EPR effect is particularly important from a therapeutic point of view, since metastases exposed to insufficient drug concentrations could serve as starting points for further dissemination of cancer cells, potentially negating the initial benefits of the treatment. This led the authors to stratify the patients according to the amount of nanomedicine present in the lesion with the lowest uptake. Although the study was underpowered to show a correlation between MM-302 uptake and progression-free survival, an encouraging trend was observed that would warrant the enrollment of additional patients. A second lesson was the good agreement between clinical and preclinical data, both in overall nanomedicine distribution and in drug concentrations in the tumors. This should strengthen the case for clinical trials when imaging-based preclinical data are encouraging. Furthermore, the authors found no correlation between drug concentrations at the tumors and either drug concentrations in the blood or tumor size. This means that blood sampling will not be predictive of efficacy and highlights the added value of quantitative whole-body imaging techniques. A limitation of this study may paradoxically reside in the use of Cu-64 as an imaging agent. PET imaging has also been used by several groups [48‐50], to show that the maximal tumor uptake of PEGylated liposomes in preclinical models occurs within 24–48 h post-administration, but imaging at later time points (e.g., 72 h) improves signal-to-background ratio. In practice, the half-life of Cu-64 limits the imaging window to approximately 48 h post-administration and even this duration requires high starting amounts of radioactivity. The use of longer-lived PET isotopes, such as Zr-89 (t_1/2 = 3.27 day) or Mn-52 (t_1/2 = 5.59 day), should overcome this barrier.

The other clinical study of a PET-radiolabeled nanomedicine was conducted by Phillips et al. [29], using fluorescent nanoparticles conjugated to iodine-124 (I-124, t_1/2 = 4.18 day), for optical and PET imaging. The nanoparticles were also conjugated to an integrin-targeting peptide and engineered to promote renal clearance, and were therefore expected to have a distinct biodistribution pattern compared to liposomal nanomedicines. Indeed, the authors observed rapid clearance of the nanoparticles with most of the activity eliminated within 72 h and no accumulation in the liver and spleen. This is an interesting feature compared to liposomal nanomedicines, where liver and spleen accumulation complicates the visualization of nearby tumors. Although the study focused mainly on the safety and stability of the nanoparticles, accumulation of the nanoparticles was observed at tumor sites in some patients, with increasing target-to-background ratios over time but already observable within 4 h of administration. This favorable pharmacokinetic profile may enable faster clinical decisions. On the other hand, the nanoparticles were observed to accumulate in the renal cortices of a patient known to have chemotherapy-induced kidney inflammation, potentially complicating the differentiation between tumor areas and inflammatory lesions. There would be no reason to expect off-tumor inflammation in preclinical models of cancer, and therefore such a chance observation could only be made in a clinical study. This shows the value of incorporating whole-body imaging at the earliest opportunity in clinical studies of nanomedicines. Furthermore, the combination with an optical probe is an excellent choice for clinical applications of multimodal imaging, allowing tumor localization by PET to be followed by fluorescence-guided surgery for improved tumor resection, ultimately resulting in improved patient outcomes.

In magnetic resonance imaging, the subject is placed in a powerful magnetic field, which will align magnetically active nuclei (most commonly hydrogen from water molecules) either parallel or anti-parallel to the magnetic field. The small difference in the number of nuclei aligning in each direction gives rise to the magnetic resonance imaging (MRI) signal. A pulsed radiofrequency can then be used to temporarily disturb the alignments of the nuclei, and the relaxation time back to the original position is measured. This relaxation time is dependent on the environment of the nuclei, for example, hydrogen nuclei in a fat-rich environment, or with short distance of an iron oxide nanoparticle, have shorter relaxation times than those in an aqueous environment. It is important to note that when using contrast agents in MRI, the measured signal arises not directly from the imaging agent but from the changes in magnetic properties the agent induces in its local environment. MRI has a much lower sensitivity than nuclear imaging techniques and requires imaging agent concentrations in the range of 10⁻³ to 10⁻⁵ mol/l, which can have pharmacological effects. Although MRI avoids the use of ionizing radiation, the inherent presence of MR-active nuclei means that at least two imaging sessions are necessary when imaging drug delivery: one before the administration of the MR-detectable agent, and one at a suitable time after administration. In addition, accurate quantification of the signal derived from contrast agents in MRI, particularly those based on superparamagnetic iron oxide materials, is difficult. On the other hand, the spatial resolution of clinical MRI is approximately 1 mm, providing far more detailed images than PET or SPECT [35].

In a recent study, Ramanathan et al. [30] described an interesting approach to image-guided drug delivery. The aim was to use the tumor deposition of Ferumoxytol, a carboxy-dextran-coated superparamagnetic iron oxide nanoparticle with long circulation time and affinity for macrophages [51], as a surrogate marker for tumor deposition of nal-IRI (MM-398, Onivyde®), a nanoliposomal formulation of the topoisomerase I inhibitor irinotecan. Both Ferumoxytol and nal-IRI are clinically approved products. The driving idea was that the amount of nanomedicine reaching the tumor would depend more on the vascular permeability at the tumor site and the average particle size than on the specific composition of the nanomedicine, so that iron nanoparticles and liposomes with otherwise comparable pharmacokinetics would reach the tumor in similar amounts. This study was performed in 13 patients with solid tumors, of which 9 were also assessed for treatment response by CT. Ferumoxytol uptake was quantified by T2* imaging (Fig. 4), and irinotecan levels were measured from patient biopsies. There was no statistically significant correlation between Ferumoxytol uptake and irinotecan levels.

In a similar two-class approach to that used by Lee et al. [28] in the PET study of MM-302 described above, the authors classified lesions according to their Ferumoxytol uptake (below or above the median of uptake in all lesions). Using this approach, lesions with above-median Ferumoxytol uptake showed significantly improved changes in size after nal-IRI treatment over those with below-median uptake. Another major finding of this study was the high variability of Ferumoxytol between patients and between lesions in a given patient, echoing the high variability of the EPR effect reported for Tc-99m- and Cu-64-labeled PEGylated liposomes [19, 28]. This MRI-based study takes a “companion diagnostic” approach akin to that used in the TSC/Doxil® combination study by Giovinazzo et al. [23]. Since the uptake of one drug is used as an indirect reflection of the uptake of a second therapeutic drug, there is an inherent possibility of pharmacokinetic/biodistribution differences between the two drugs. Correlations must therefore be established in preliminary studies for each envisaged reporter/drug combination before the pair can be used in the clinic. However, the use of clinically approved imaging agents could easily be integrated into existing treatment protocols by not having to go through the same regulatory hurdles as theranostic agents, which could be considered as new drugs and therefore require full regulatory approval.

Two other clinical trials (NCT02022644 and NCT03086616) of nal-IRI that include image-guided drug delivery are planned. Convection-enhanced delivery (CED) of nal-IRI to the brain of pediatric and adult patients with glioma will be followed in real time by MRI, using co-administered gadolinium-based contrast agents.

Ultrasound imaging relies on sending sound waves through the body and recording the reflected waves to produce a high-resolution 2D image. This is done with a hand-held probe, making it a widely available and very cost-effective technique, but is mostly limited to soft tissue imaging [35]. There is a large body of preclinical work on focused ultrasound (FUS)-mediated drug delivery, especially using thermosensitive liposomes, with the imaging aspect typically performed by ultrasound or MRI. For further information on this topic, the reader is directed to recent and extensive reviews [52‐54]. We have found only one report related to ultrasound-guided drug delivery in humans. Lyon et al. [31] recently described the protocol of an ongoing (as of April 2018) clinical trial of ThermoDox®, a thermosensitive liposomal formulation of doxorubicin with FDA approval for investigational use. By using low-intensity FUS to visualize liver tumors and induce mild hyperthermia, the aim is to selectively increase the concentration of doxorubicin at the tumor sites. Doxorubicin levels will be measured by high-performance liquid chromatography in biopsied tumor tissues before and after application of FUS. Only the first few patients are to undergo tumor biopsy before FUS, to establish an average tumor concentration of doxorubicin prior to FUS application. The authors describe this as a way of reducing the number of invasive procedures performed on the patients. However, considering the variability of liposomal uptake in tumors highlighted in the MM-302 study [28], we caution that this approach might yield misleading results. It would be preferable, especially for a pilot study, to determine pre-FUS doxorubicin concentration in as many patients as possible to adequately quantify the effect of FUS on liposomal drug release. Other imaging modalities such as [¹⁸F]FDG PET-CT and dynamic-contrast enhanced (DCE)-MRI are included in the study, but aimed at establishing baseline tumor imaging and potential response to treatment rather than evaluating drug delivery. Results from this study have yet to be published; however, it will be of considerable interest to see whether a non-invasive and non-ionizing method such as FUS can be used to increase doxorubicin concentrations above therapeutic threshold specifically in cancerous tissue to minimize the effect on healthy tissues.

Imaging has been successfully used in humans to study the biodistribution and pharmacokinetics of nanomedicine-based drug delivery systems, demonstrating its value for this purpose. Significant findings from these studies include solid proof that (1) EPR as the most common uptake mechanism for nanomedicines in tumors/inflamed tissues is a real phenomenon in patients and (2) the EPR effect is highly heterogeneous, between diseases, patients, and even lesions within a single patient. This heterogeneity may underlie the fact that nanomedicines have not always shown superiority in clinical therapeutic activity over conventional drugs, despite an improved safety profile [11]. Indeed, an absence of therapeutic effect does not imply absence of nanomedicine accumulation in tumors. This is particularly relevant for metastatic cancers, as nanomedicine accumulation only at certain tumor sites may not be sufficient for an overall survival benefit to the patient. Moreover, recent clinical studies have demonstrated a clear correlation between nanomedicine accumulation levels in target tissues (e.g., tumors) and therapeutic effect, supporting the use of imaging to identify patients that will respond to the treatment. An important concept that arises from these studies is the development of companion diagnostics, based on clinically approved imaging agents that correlate with nanomedicine biodistribution. Another conclusion from this review is that most of the studies to date have been in the oncology field, leaving further opportunities for image-guided drug delivery studies beyond this area, particularly in the fields of infection and respiratory medicine.

A general limitation of the nanomedicine-imaging approaches described in this review is that they are in practice indirect methods. Indeed, the imaging agent is most frequently attached to the carrier rather than to the drug, whereas clinically the most relevant information is the localization of the drug itself, which may differ from that of the carrier after release. This would generally require chemical modification of the drug. Furthermore, it is extremely challenging to differentiate between nanocarrier-bound and released drug by non-invasive imaging. This may be possible by optical imaging, especially for intrinsically fluorescent drugs, in vitro and possibly at the preclinical level, but not in humans [55]. An option is co-loading liposomes with a drug and a magnetic resonance (MR) contrast agent, as the relaxivity of the encapsulated and non-encapsulated MR contrast agent will differ [56], but this method suffers from the inherent limitations of MRI discussed above (sensitivity, challenging whole-body detection/quantification). Furthermore, it will not inform on drug distribution after release and at later times. Nuclear imaging modalities may be helpful in this context, for example, by loading radiolabeled drugs into nanocarriers; however, the half-lives of the radioisotopes most amenable to radiolabeling of small molecules (e.g., C-11 and F-18) are too short to match the biological half-lives of nanomedicines. In this context, a recent preclinical study demonstrated the concept of radiolabeling both the liposome carrier and the encapsulated drug with PET radionuclides [57]. Another possibility is to use multi-isotope SPECT and image both the carrier and the drug orthogonally; however, this is only possible when using radionuclides with different gamma emission energies (e.g., Tc-99m and In-111). Longer imaging windows are attainable by using metal-chelating drugs and radiometals such as Zr-89 [48]; however, this raises another issue, which is the stability of the free radionuclide/label. Even the longer-lived and covalently bound radioiodine (I-124, I-125, I-131) labels are susceptible to deiodination in vivo. As mentioned previously, the accumulation of the free radiolabel in specific anatomical locations (e.g., the thyroid for radioiodine, bones for Zr-89, or pancreas for Mn-52 [58]) may inform on the extent of drug release from the carrier. Even this requires the assumption that the rate of release of the radiolabel from the drug is similar to the drug release from the carrier and will not inform about drug localization.

Despite all these issues, it is clear that among the different imaging techniques available, nuclear medicine techniques have been the most used to date, most likely due to their whole-body capabilities and excellent quantification properties. Importantly, their high sensitivity also allows imaging with sub-therapeutic nanomedicine doses in the microdose range (1 % of the therapeutic dose), which facilitates clinical translation. MRI and US circumvent the use of radioactivity and provide higher spatio-temporal resolution, at the expense of lower sensitivity and higher imaging agent doses. In addition, performing quantitative whole-body imaging with MRI and US is a more complex process than with nuclear imaging. For these reasons, it is likely that future clinical studies in this area will include nuclear imaging as the main quantitative method to assess nanomedicine/drug concentration in vivo. The recent study by Lee et al. [28] using [⁶⁴Cu]MM-302 is an excellent example of the way clinical image-guided drug delivery studies should be conducted nowadays, particularly for its approach to patient stratification. We believe that incorporating imaging into studies of nanomedicine drug delivery will undoubtedly provide valuable additional information that standard techniques such as blood sampling and biopsy cannot provide. This will greatly benefit the clinical development of new nanomedicines and help achieve the full potential of those already developed.