Long-circulating liposomes radiolabeled with [18F]fluorodipalmitin ([18F]FDP)

Mařı́k, Jan; Tartis, Michaelann; Zhang, Hua; Fung, Jennifer; Kheirolomoom, Azadeh; Sutcliffe, Julie L.; Ferrara, Katherine W.

doi:10.1016/j.nucmedbio.2006.12.004

Cited by 99 publications

(97 citation statements)

References 35 publications

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“…With the exception of studies involving CRRRR, in all data reported here and in [25], activity in the bladder increased only after a delay of ~1000 seconds. With particles containing CRRRR, activity in the bladder increased immediately after injection of the particles, with this difference hypothesized to result from immediate cellular internalization of these particles or rapid extracellular enzymatic breakdown of the radiolabeled lipid.…”

Section: Discussioncontrasting

confidence: 47%

Section: Introductionmentioning

confidence: 99%

“…Here, in order to facilitate high-resolution pharmacodynamic measurements, we employ 18 F for PET trafficking of peptide-targeted liposomes (Figure 1), using an 18 [25]. When free lipid is injected or the vehicle is recognized and metabolized by the RES, the 18 F-containing metabolite rapidly clears from the liver, facilitating real-time evaluation of the dynamics [25]. Other advantages of the [ 18 F]FDP label include the absence of any change in surface properties due to the effects of chelators, the small size of the 18 F group attached to the lipid head group, the simplicity of the labeling, and the generality of the approach.…”

Section: Introductionmentioning

confidence: 99%

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Dynamic imaging of arginine-rich heart-targeted vehicles in a mouse model

Zhang

Kusunose²,

Kheirolomoom³

et al. 2008

Biomaterials

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Efficacious delivery of drugs and genes to the heart is an important goal. Here, a radiolabeled peptidetargeted liposome was engineered to bind to the heart, and the biodistribution and pharmacokinetics were determined by dynamic positron emission tomography in the FVB mouse. Efficient targeting occurred only with an exposed ligand and a dense concentration of peptide (6000 peptides/particle). Liposomes targeted with CRPPR or other arginine-rich peptides with an exposed guanidine moiety bound within 100 seconds after intravenous injection and remained stably bound. With CRPPRtargeted particles, the radioisotope density in the heart averaged 44 ± 9% injected dose per gram of tissue, more than 30 fold higher than in skeletal muscle. The rapid and efficient targeting of these particles can be exploited in drug and gene delivery systems and with dynamic positron emission tomography provides a model system to optimize targeting of engineered particles.

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Section: Discussioncontrasting

confidence: 47%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Dynamic imaging of arginine-rich heart-targeted vehicles in a mouse model

Zhang

Kusunose²,

Kheirolomoom³

et al. 2008

Biomaterials

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“…Creation of a clinically-optimized ultrasound-enhanced drug or gene delivery vehicle is challenging due to the vast parameter space of potential materials, targeting ligands, cargos, and ultrasound parameters. We and others are developing cross-modality imaging methods in which nuclear medicine, magnetic resonance imaging, and optical imaging probes are used to visualize the delivery vehicle or the model drug [51][52][53][54].The great strength of nuclear imaging techniques, particularly positron emission tomography, is the real-time and highly sensitive full-body pharmacokinetics currently possible in pre-clinical studies [54,55]. Magnetic resonance imaging (MRI) techniques can be used to visualize the biodistribution of drugs or vehicles [52] and the activation of delivery vehicles in limited cases [51], and MRI can also be used to monitor local temperature in pre-clinical and clinical studies [56].…”

Section: Other Issuesmentioning

confidence: 99%

Driving delivery vehicles with ultrasound

Ferrara

2008

Advanced Drug Delivery Reviews

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162

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Therapeutic applications of ultrasound have been considered for over 40 years, with the mild hyperthermia and associated increases in perfusion produced by ultrasound harnessed in many of the earliest treatments. More recently, new mechanisms for ultrasound-based or ultrasound-enhanced therapies have been described, and there is now great momentum and enthusiasm for the clinical translation of these techniques. This dedicated issue of Advanced Drug Delivery Reviews, entitled "Ultrasound for Drug and Gene Delivery," addresses the mechanisms by which ultrasound can enhance local drug and gene delivery and the applications that have been demonstrated at this time. In this commentary, the identified mechanisms, delivery vehicles, applications and current bottlenecks for translation of these techniques are summarized. KeywordsUltrasound; Therapy; Drug delivery; Gene delivery; Sonoporation; Cavitation As an imaging modality, ultrasound is widely employed and valued for its real time applications, low cost, simplicity, and safety. Waves of alternating increased and decreased pressure propagate from the transducer, typically resulting in a maximum intensity in a focal region chosen by the operator. The dimensions of the focal region can vary from tens of microns for high frequency ultrasound to centimeters for an unfocused therapeutic beam. Most clinical instruments are engineered to effectively image from the body surface to 24 or more centimeters in depth. The ability to locally control and maximize energy deposition deep within the body facilitates a broad range of clinical opportunities for ultrasound imaging and therapy. Developing over four decades, clinical and commercial application of ultrasonic therapies spans hyperthermia, drug delivery, lipoplasty, and thrombolysis [1,2]. A complete and precise summary of the potential applications for ultrasonic enhancement of drug and gene delivery remains challenging as the mechanisms are multiple and not fully characterized. From an engineering viewpoint, the methods by which ultrasound facilitates drug and gene delivery can be summarized as direct changes in the biological or physiological properties of tissues facilitating transport, direct changes in the drug or vehicle increasing bioavailability or enhancing efficacy, and indirect effects by which ultrasound acts on the vehicle to produce changes in the surrounding tissue. While there are common mechanisms between these methods, the engineering challenges associated with the optimization of ultrasound systems and drug and vehicle design are unique for each method. Promising examples of each of these methods can be identified at this time and are addressed below.☆ This commentary is part of the Advanced Drug Delivery Reviews theme issue on "Ultrasound in Drug and Gene Delivery".

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“…To prolong persistence of the therapeutic agent in vivo, polyethylene glycol-coated phospholipid liposomes have been designed that delay clearance from the circulation (Marik et al, 2007). Therapeutic nanocarriers are usually functionalized with biorecognition moieties on the surface such as peptides or antibodies to enable in vivo delivery of the therapy to the intended site such as the macrophage (Günther et al, 2011).…”

Section: Nanocarriersmentioning

confidence: 99%