Acoustically-active microbubbles conjugated to liposomes: Characterization of a proposed drug delivery vehicle

Kheirolomoom, Azadeh; Dayton, Paul A.; Lum, Aaron F.H.; Little, Erika; Paoli, Eric; Zheng, Hairong; Ferrara, Katherine W.

doi:10.1016/j.jconrel.2006.12.015

Cited by 206 publications

(179 citation statements)

References 44 publications

(41 reference statements)

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“…The lipid shell expands, buckles and compresses with each acoustic cycle, recoating as needed to cover bubble fragments [27][28][29][30][31][32]. A thick layer of DNA can be applied to the surface or, alternatively, liposomes or other nanoparticles can be attached to the membrane, each enhancing the payload [16,33,34]. Protein and polymer-shelled microbubbles have also been functionalized to carry targeting ligands [35] and genetic payloads [36,37].…”

Section: Vehiclesmentioning

confidence: 99%

Driving delivery vehicles with ultrasound

Ferrara

2008

Advanced Drug Delivery Reviews

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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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Section: Vehiclesmentioning

confidence: 99%

Driving delivery vehicles with ultrasound

Ferrara

2008

Advanced Drug Delivery Reviews

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225

162

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“…In this case the destruction of microbubbles leads to the release of the drug and ex-travasation of the drug due to the increased number of pores in the vasculature. Recent examples of this strategy are the delivery of the antisense androgen receptor oligodeoxynucleotide in vivo, resulting in inhibition of prostate tumor growth (79), and the use of a conjugation between microbubbles and liposomes carrying the payload (80). The feasibility of both strategies has been proven mainly by using (reporter) genes as payload (81)(82)(83).…”

Section: Ultrasound-facilitated Drug Deliverymentioning

confidence: 99%

The role of ultrasound and magnetic resonance in local drug delivery

Deckers

Rome

Moonen

2008

Magnetic Resonance Imaging

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Local drug delivery has recently attracted much attention since it represents a strategy to increase the drug concentration at the target location and decrease systemic toxicity effects. Ultrasound can be used in different ways to trigger regional drug delivery. It can cause the local drug release from a carrier vehicle and the local increase of cell membrane permeability either by a mechanical action or by a temperature increase. Ultrasound contrast agents may enhance these effects by means of cavitation. Ultrasound can be focused deep inside the body into a small region with dimensions on the order of 1 mm. Several types of drug microcarriers have been proposed, from nano-to micrometer sized particles. The objective of real-time imaging of local drug delivery is to assure that the delivery takes place in the target region, that the drug concentration and the resulting physiological reaction are sufficient, and to intervene if necessary. Ultrasound and nuclear imaging techniques play an important role. MRI is rather insensitive but allows precise targeting of (focused) ultrasound, can provide real-time temperature maps, and gives access to a variety of imaging biomarkers that may be used to assess drug action. Examples from recent articles illustrate the potential of the principles of ultrasound-triggered local drug delivery.

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“…Efforts have been made to improve drug loading by incorporating phospholipids 20 or surfactants 21 into the shell, or coupling drug-loaded liposomes to the microbubble surface. 18,22 The latter approach takes full advantage of the high drug-loading capacity of liposomes and the ultrasound-mediated BBB disruption effect of microbubbles. For example, Lentacker et al 18 coupled doxorubicin-loaded liposomes to microbubbles via a biotin-avidin linkage.…”

Section: Introductionmentioning

confidence: 99%

Microbubbles coupled to methotrexate-loaded liposomes for ultrasound-mediated delivery of methotrexate across the blood–brain barrier

Xiang¹,

Liu²,

Yang³

et al. 2014

IJN

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Methotrexate (MTX) is the single most effective agent for the treatment of primary central nervous system lymphoma. Currently, the delivery of MTX to the brain is achieved by high systemic doses, which cause severe long-term neurotoxicity, or intrathecal administration, which is highly invasive and may lead to infections or hemorrhagic complications. Acoustically active microbubbles have been developed as drug carriers for the noninvasive and brain-targeted delivery of therapeutics. However, their application is limited by their low drug-loading capacity. To overcome this limitation, we prepared microbubbles coupled to MTX-loaded liposomes using ZHIFUXIAN, a novel type of microbubbles with a superior safety profile and long circulation time. MTX-liposome-coupled microbubbles had a high drug-loading capacity of 8.91%±0.86%, and their size (2.64±0.93 μm in diameter) was suitable for intravenous injection. When used with ultrasound, they showed more potent in vitro cytotoxicity against Walker-256 cancer cells than MTX alone or MTX-loaded liposomes. When Sprague-Dawley rats were exposed to sonication, administration of these MTX-liposome-coupled microbubbles via the tail vein led to targeted disruption of the blood–brain barrier without noticeable tissue or capillary damage. High-performance liquid chromatography analysis of the brain MTX concentration showed that MTX delivery to the brain followed the order of MTX-liposome-coupled microbubbles + ultrasound (25.3±2.4 μg/g) > unmodified ZHIFUXIAN + MTX + ultrasound (18.6±2.2 μg/g) > MTX alone (6.97±0.75 μg/g) > MTX-liposome-coupled microbubbles (2.92±0.39 μg/g). Therefore, treatment with MTX-liposome-coupled microbubbles and ultrasound resulted in a significantly higher brain MTX concentration than all other treatments ( P <0.01). These results suggest that MTX-liposome-coupled microbubbles may hold great promise as new and effective therapies for primary central nervous system lymphoma and other central nervous system malignancies.

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Acoustically-active microbubbles conjugated to liposomes: Characterization of a proposed drug delivery vehicle

Cited by 206 publications

References 44 publications

Driving delivery vehicles with ultrasound

Driving delivery vehicles with ultrasound

The role of ultrasound and magnetic resonance in local drug delivery

Microbubbles coupled to methotrexate-loaded liposomes for ultrasound-mediated delivery of methotrexate across the blood–brain barrier

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Acoustically-active microbubbles conjugated to liposomes: Characterization of a proposed drug delivery vehicle

Cited by 206 publications

References 44 publications

Driving delivery vehicles with ultrasound

Driving delivery vehicles with ultrasound

The role of ultrasound and magnetic resonance in local drug delivery

Microbubbles coupled to methotrexate-loaded liposomes for ultrasound-mediated delivery of methotrexate across the blood&ndash;brain barrier

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Product

Resources

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Microbubbles coupled to methotrexate-loaded liposomes for ultrasound-mediated delivery of methotrexate across the blood–brain barrier