Theory of paramagnetic contrast agents in liposome systems

Gadolinium-Loaded Polychelating Polymer-Containing Tumor-Targeted Liposomes

Magnetic resonance (MR) is one of the most widely used imaging modalities in contemporary medicine to obtain images of pathological areas. Still, there is a big effort to facilitate the accumulation of contrast in the required zone and further increase a local spatial concentration of a contrast agent for better imaging. Certain particulate carriers able to carry multiple contrast moieties can be used for an efficient delivery of contrast agents to areas of interest and enhancing a signal from these areas. Among those carriers, liposomes draw special attention because of their easily controlled properties and good pharmacological characteristics. To enhance the signal intensity from a given reporter metal in liposomes, one may attempt to increase the net quantity of carrier-associated reporter metal by using polylysine (PLL)-based polychelating amphiphilic polymers (PAP). In addition to heavy load of reporter metal onto the pharmaceutical nanocarrier (liposome), the accumulation of the contrast nanoparticles in organs and tissues of interest (such as tumors) can be significantly enhanced by targeting such particles both "passively," via the so-called enhanced permeability and retention (EPR) effect, or "actively," using various target-specific ligands, such as monoclonal antibodies. Combining three different properties-heavy load with gadolinium (Gd) via the liposome membrane-incorporated PAP and tumor specificity mediated by the liposome-attached mAb 2C5-in a single nanoparticle of long-circulating (PEGylated) liposomes could provide a new contrast agent for highly specific and efficient tumor MRI.

Neuroimaging in Alzheimer's disease: preclinical challenges toward clinical efficacy

The scope of this review focuses on recent applications in preclinical and clinical magnetic resonance imaging (MRI) toward accomplishing the goals of early detection and responses to therapy in animal models of Alzheimer's disease (AD). Driven by the outstanding efforts of the Alzheimer's Disease Neuroimaging Initiative (ADNI), a truly invaluable resource, the initial use of MRI in AD imaging has been to assess changes in brain anatomy, specifically assessing brain shrinkage and regional changes in white matter tractography using diffusion tensor imaging. However, advances in MRI have led to multiple efforts toward imaging amyloid beta plaques first without and then with the use of MRI contrast agents. These technological advancements have met with limited success and are not yet appropriate for the clinic. Recent developments in molecular imaging inclusive of high-power liposomal-based MRI contrast agents as well as fluorine 19 ((19)F) MRI and manganese enhanced MRI have begun to propel promising advances toward not only plaque imaging but also using MRI to detect perturbations in subcellular processes occurring within the neuron. This review concludes with a discussion about the necessity for the development of novel preclinical models of AD that better recapitulate human AD for the imaging to truly be meaningful and for substantive progress to be made toward understanding and effectively treating AD. Furthermore, the continued support of outstanding programs such as ADNI as well as the development of novel molecular imaging agents and MRI fast scanning sequences will also be requisite to effectively translate preclinical findings to the clinic.

Multifunctional, stimuli-sensitive nanoparticulate systems for drug delivery

The use of nanoparticulate pharmaceutical drug delivery systems (NDDSs) to enhance the in vivo effectiveness of drugs is now well established. The development of multifunctional and stimulus-sensitive NDDSs is an active area of current research. Such NDDSs can have long circulation times, target the site of the disease and enhance the intracellular delivery of a drug. This type of NDDS can also respond to local stimuli that are characteristic of the pathological site by, for example, releasing an entrapped drug or shedding a protective coating, thus facilitating the interaction between drug-loaded nanocarriers and target cells or tissues. In addition, imaging contrast moieties can be attached to these carriers to track their real-time biodistribution and accumulation in target cells or tissues. Here, I highlight recent developments with multifunctional and stimuli-sensitive NDDSs and their therapeutic potential for diseases including cancer, cardiovascular diseases and infectious diseases.

Design and synthesis of novel functional lipid-based bioconjugates for drug delivery and other applications

The modification of biologicals such as proteins/peptides, small molecules, and other polymers with lipids provides an efficient method for mediating their insertion into liposomes and lipid-core micellar nanocarriers. In this chapter, we describe several representative protocols developed in our laboratory for the bioconjugation of liposomes and lipid-core micelles for drug/gene delivery and diagnostic imaging applications.

Gadolinium-loaded polychelating polymer-containing tumor-targeted liposomes

Magnetic resonance (MR) is one of the most widely used imaging modalities in contemporary medicine to obtain images of pathological areas. Still, there is a big effort to facilitate the accumulation of contrast in the required zone and further increase a local spatial concentration of a contrast agent for better imaging. Certain particulate carriers able to carry multiple contrast moieties can be used for an efficient delivery of contrast agents to areas of interest and enhancing a signal from these areas. Among those carriers, liposomes draw special attention because of their easily controlled properties and good pharmacological characteristics. To enhance the signal intensity from a given reporter metal in liposomes, one may attempt to increase the net quantity of carrier-associated reporter metal by using polylysine (PLL)-based polychelating amphiphilic polymers (PAP). In addition to heavy load of reporter metal onto the pharmaceutical nanocarrier (liposome), the accumulation of the contrast nanoparticles in organs and tissues of interest (such as tumors) can be significantly enhanced by targeting such particles both "passively," via the so-called enhanced permeability and retention (EPR) effect, or "actively," using various target-specific ligands, such as monoclonal antibodies. Combining three different properties--heavy load with Gd via the liposome membrane-incorporated PAP and tumor specificity mediated by the liposome-attached mAb 2C5--in a single nanoparticle of long-circulating (PEGylated) liposomes could provide a new contrast agent for highly specific and efficient tumor MRI.

Paramagnetic thermosensitive liposomes for MR-thermometry

MR-thermometry methods have been developed for the guidance and control of thermal therapies such as thermal ablation or regional hyperthermia. However, they are limited to the measurement of temperature changes and, thus, cannot be used to assess absolute temperature values. Paramagnetic thermosensitive liposomes are innovative contrast agents offering the potential to overcome these limitations. They are composed of a gadolinium- or manganese-based compound enclosed by a phospholipid membrane with a distinct gel-to-liquid crystalline phase transition temperature (Tm). At this temperature, the phospholipid membrane changes from a gel-phase to a liquid-crystalline phase which is associated with an increased transmembrane permeability towards solutes and water. Under these conditions, both types of paramagnetic thermosensitive liposomes demonstrate a significant increase in longitudinal (T1) relaxivity, attributed to the release of paramagnetic material from the liposome and/or to the increased water exchange rate between the liposome interior and exterior. Paramagnetic thermosensitive liposomes have already been successfully studied in animal models and have demonstrated a clear correlation between tissue temperature changes and signal intensity changes in MRI. Nevertheless, before entering clinical trials they have to be studied in more detail with regard to dose, pharmacokinetics and toxicity.

Multifunctional and stimuli-sensitive pharmaceutical nanocarriers

Currently used pharmaceutical nanocarriers, such as liposomes, micelles, and polymeric nanoparticles, demonstrate a broad variety of useful properties, such as longevity in the body; specific targeting to certain disease sites; enhanced intracellular penetration; contrast properties allowing for direct carrier visualization in vivo; stimuli-sensitivity, and others. Some of those pharmaceutical carriers have already made their way into clinic, while others are still under preclinical development. In certain cases, the pharmaceutical nanocarriers combine several of the listed properties. Long-circulating immunoliposomes capable of prolonged residence in the blood and specific target recognition represent one of the examples of this kind. The engineering of multifunctional pharmaceutical nanocarriers combining several useful properties in one particle can significantly enhance the efficacy of many therapeutic and diagnostic protocols. This paper considers the current status and possible future directions in the emerging area of multifunctional nanocarriers with primary attention on the combination of such properties as longevity, targetability, intracellular penetration, contrast loading, and stimuli-sensitivity.

T1 relaxivity of core-encapsulated gadolinium liposomal contrast agents--effect of liposome size and internal gadolinium concentration

RATIONALE AND OBJECTIVES

Long circulating core-encapsulated gadolinium (CE-Gd) liposomal nanoparticles that have surface conjugated polyethylene glycol are a promising platform technology for use as blood pool T1-based magnetic resonance (MR) contrast agents. The objective of this study was to investigate the effect of liposome size and internal (core) Gd concentration on the T1 relaxivity of CE-Gd liposomes.

MATERIALS AND METHODS

Twelve different liposomal formulations were synthesized and characterized, resulting in a size (50, 100, 200, and 400 nm) and core Gd-concentration (200, 350, and 500 mM) "matrix" of test samples. Subsequently, CE-Gd liposomes were diluted in deionized water (four diluted samples) and molar T1 relaxivity (r1) measurements were performed at 2- and 7-T MR field strengths.

RESULTS

The r1 of CE-Gd liposomes was inversely related to the liposome size. The largest change in r1 was observed between liposomes that were extruded through 50- and 100-nm filter membranes. At both field strengths, the variation in internal gadolinium concentration did not show any significant correlation (alpha < or = 0.05) with r1.

CONCLUSIONS

The size of CE-Gd liposomal nanoparticles significantly affects the T1 relaxivity. An inverse relation was observed between liposome size and T1 relaxivity. The T1 relaxivity did not change significantly with core Gd concentration over the measured concentration range.

High-resolution MRI characterization of human thrombus using a novel fibrin-targeted paramagnetic nanoparticle contrast agent

In this study, the sensitivity of a novel fibrin-targeted contrast agent for fibrin detection was defined in vitro on human thrombus. The contrast agent was a lipid-encapsulated perfluorocarbon nanoparticle with numerous Gd-DTPA complexes incorporated into the outer surface. After binding to fibrin clots, scanning electron microscopy of treated clots revealed dense accumulation of nanoparticles on the clot surfaces. Fibrin clots with sizes ranging from 0.5-7.0 mm were imaged at 4.7 T with or without treatment with the targeted contrast agent. Regardless of sizes, untreated clots were not detectable by T(1)-weighted MRI, while targeted contrast agent dramatically improved the detectability of all clots. Decreases in T(1) and T(2) relaxation times (20-40%) were measured relative to the surrounding media and the control clots. These results suggest the potential for sensitive and specific detection of microthrombi that form on the intimal surfaces of unstable atherosclerotic plaque.

Relaxation rates of blood with osmotically modified red cell volume: application of the two-compartment fast exchange model

Blood has been considered as a simplified tissue model, both physiologically and physically consisting in two compartments, extra-cellular and intra-cellular. In the physiologic condition (300 mOsm), the relaxation rates of red cell suspensions in saline increased linearly with the hematocrit in the range 0-0.80 according to Fullerton's model of fast proton exchanges between the two compartments (Fullerton GD, Potter JL, Dornbluth NC. NMR relaxation of protons in tissues and other macromolecular water solutions. Magn Reson Imaging 1982; 1:209-228). In experiments of osmotic variations, between 200 and 900 mOsm at three constant red cell numbers in the samples, non-linear variations of relaxation rates with red cell volume were observed. In the hyperosmotic domain, the particularly high increase in blood transverse relaxation rate with the decreasing cell volume has been attributed to the progressive water-protein organization in the cellular compartment. A generalised form of the fast exchange model has been applied to extended experimental conditions of red cells, by introducing the red cell volume ratio of modified to iso-osmotic values, and the volume fraction of iso-osmotic red cells.

Theory of heterogeneous relaxation in compartmentalized tissues

A new model of compartmentalized relaxation--that which occurs for spins (protons) exchanging between compartments of different relaxation rates--is presented. This model generalizes previous ones by allowing spatially dependent relaxation within compartments. Solutions for the diffusion-Bloch equations are found via an efficient numerical technique known as the generalized moment expansion, and they agree well with the solutions to the standard two-site exchange equations (TSEE) for many typical situations. Specific models are developed for liposomes, red blood cells, capillaries, and arteries with respect to applied contrast agents. A parameter derived from tissue characteristics is introduced to predict the nature of the solutions. A new method is proposed for using contrast agents to detect capillaries, which exploits their high surface-to-volume ratio relative to the other elements of the vasculature.

Intestinal absorption of Mn-mesoporphyrin in a small bowel sac system: effect of oleic acid

RATIONALE AND OBJECTIVES

The authors investigated the effect of oleic acid (cis-9-octadecenoic acid) (OA), a lipidic carrier, on the intestinal absorption rate and T1 relaxation time of manganese (III) mesoporphyrin (Mn-mesoporphyrin), a prototype hepatobiliary contrast agent for magnetic resonance imaging.

METHODS

Mn-mesoporphyrin was formulated with OA at various concentrations. Small bowel sacs were created in 36 rats and filled with complexed and free Mn-mesoporphyrin. Intestinal absorption of Mn-mesoporphyrin was measured with spectrophotometry at 364 nm. T1 relaxation times were measured in samples of Mn-mesoporphyrin solutions, bowel wall, liver, and bile.

RESULTS

Absorption rates ranged from 4.2%/cm2/h to 13%/cm2/h. Absorption was greatest (13%/cm2/h) when a combination of 1 mmol/L Mn-mesoporphyrin and 26.5 mmol/L OA was used. The T1 of bile decreased from 2,480 to 248 msec (maximum decrease) in rats that received Mn-mesoporphyrin.

CONCLUSION

Mn-mesoporphyrin is absorbed from the small bowel in both the lipid-associated and free form, resulting in substantial shortening of the T1 in bile.

Cortical and subcortical chemical pathology in Alzheimer's disease as assessed by multislice proton magnetic resonance spectroscopic imaging

BACKGROUND

Multislide proton magnetic resonance spectroscopic imaging (1H-MRSI) permits the simultaneous acquisition of N-acetylaspartate (NA), choline (Cho), creatine/phosphocreatine (Cre), and lactate (Lac) signal intensities from four 15-mm slices divided into 0.84-ml single-volume elements. NA is inferred to be a neuron-specific molecule, whereas Cho mainly reflects glycerophosphocholine and phosphocholine, compounds involved in phospholipid metabolism.

OBJECTIVE

To assess whether 1H-MRSI could detect a regional pattern of cortical and subcortical involvement in the brain of Alzheimer's disease (AD) patients.

METHODS

1H-MRSI was performed in 15 patients with probable AD and 15 age-matched healthy controls. Regions of interest (ROIs) were selected from frontal (FC), temporal (TC), parietal (PC), occipital, and insular cortices, subcortical white matter (WM), and thalamus.

RESULTS

In AD patients, we found a significant reduction of NA/Cre in the FC, TC, and PC and a significant reduction of Cho/Cre in the WM.

CONCLUSIONS

This 1H-MRSI study of AD patients shows a regional pattern of neuronal damage in the associative cortices, as revealed by significant reduction of NA/Cre in the FC, TC, and PC, and regional derangement of phospholipid metabolism, as revealed by significant reduction of Cho/Cre in the WM.

Liposomes as delivery agents for medical imaging

Medical imaging requires an appropriate intensity of signal from the area of interest in order to differentiate certain structures from surrounding tissues, regardless of the modality used. In the majority of cases, contrast agents specific for each imaging modality are necessary to achieve a sufficiently intense signal. To facilitate the accumulation of contrast in the required zone, various microparticulates have been suggested as carriers for contrast agents. Among these carriers, liposomes-microscopic artificial phospholipid vesicles-draw special attention because of their easily controlled properties and useful pharmacological characteristics. This review will discuss how the advantages of liposomes have been used so far in the rapidly growing field of diagnostic medical imaging.

Theory of contrast agents in magnetic resonance imaging: coupling of spin relaxation and transport

The role of diffusive transport on the enhancement of nuclear spin relaxation through NMR contrast agents is described by means of diffusion-Bloch equations. These equations are solved in the mean relaxation time approximation [W. Nadler and K. Schulten, J. Chem. Phys. 82, 151-160 (1985)]. A model presented considers relaxation enhancement in tissue in which contrast agents confined to intravascular spaces affect nuclear spin in the extravascular volume. We show how the mean relaxation time depends on capillary density, on permeability, and on diffusion. A second model describes enhanced phase relaxation of liver tissue in the presence of magnetic particles in Kupffer cells. The relationship between relaxation rate and density of Kupffer cells is investigated. The diagnostic value of enhanced nuclear relaxation in the presence of contrast agents is discussed on the basis of the systematic mathematical results obtained.