Synthesis of Phase-shift Nanoemulsions with Narrow Size Distributions for Acoustic Droplet Vaporization and Bubble-enhanced Ultrasound-mediated Ablation

High-intensity focused ultrasound (HIFU) is used clinically to thermally ablate tumors.¹ To enhance localized heating and improve thermal ablation in tumors, lipid-coated perfluorocarbon droplets have been developed which can be vaporized by HIFU. The vasculature in many tumors is abnormally leaky due to their rapid growth.² Thus, nanoparticles are able to penetrate the fenestrations and passively accumulate within tumors, a process known as the enhanced permeability and retention (EPR) effect.³ It has been shown that nanoparticles between 70 and 200 nm accumulate most efficiently in tumors.⁴ The procedure described in this report produces a stable phase-shift nanoemulsion (PSNE) of lipid-coated perfluorocarbon droplets with a narrow size distribution. In the past, most studies used polydisperse size distributions of PSNE, but recent studies have focused on producing PSNE with narrow size distributions.^{5, 6} The extrusion method described in this protocol allows one to control the size in order to increase the percentage of droplets administered systemically that will accumulate within tumors.

The dodecafluoropentane core of the nanodroplets has a boiling temperature of 29 °C.⁷ Thus, it is important to maintain a low temperature during each step of the PSNE preparation. Sonication increases the temperature of the solution, but using a pulsed sonication sequence and placing the sample in an ice-water bath during sonication can reduce evaporation. Once the lipid-coated droplets have formed, the boiling temperature increases above 60 °C due to surface tension.⁸ PSNE vaporization is temperature- and pressure-dependent and also depends on the size and composition of the liquid perfluorocarbon droplets.⁹ For example, it was found that peak rarefactional pressures above 3.8 MPa were needed to vaporize 200 nm DDFP droplets at 37 °C.¹⁰ Coating the droplets with lipids conjugated with poly(ethylene glycol) (PEG) inhibits fusion, thus increasing the size stability of PSNE over multiple days. Additionally, it has been documented that PEG can increase the circulation time of lipid-based vesicles,^11-13 which may increase the fraction of systemically administered PSNE that accumulate in localized malignancies.^{14, 15}

The perfluorocarbon droplets can be suspended in a tissue-mimicking polyacrylamide hydrogel phantom containing albumin for in vitro thermal ablation studies.¹⁶ The PSNE-loaded hydrogels are useful for assessing the vaporization thresholds as well as studying lesion formation from bubble-enhanced HIFU-mediated heating. The hydrogels absorb and convert acoustic energy into heat, and once the temperature in the hydrogel exceeds 58°C, albumin in the hydrogel denatures and becomes opaque.¹⁷ Because the hydrogels are optically transparent, it is possible to observe protein denaturation in real time. Vaporization of PSNE within the hydrogels creates bubbles, which are used to increase the efficiency of ultrasound-mediated heating. Using a focused transducer, PSNE vaporization and bubble-enhanced heating can be localized, thus avoiding unwanted heating in intervening biological media (i.e. tissue). In the phantoms, the vaporized bubble cloud can affect the ultrasound beam propagation and cause prefocal heating, provided the acoustic power exceeds a threshold. Below this threshold, the scattered power is too low to ablate tissue in the prefocal region; consequently, the ablated volume is confined to the location of the bubble cloud. The use of PSNE to enhance localized heating in vivo could potentially improve outcomes of HIFU tumor ablation therapies. As a first step, an extrusion-based protocol has been developed to control the size of narrowly distributed PSNE. Using PSNE dispersed within optically-transparent tissue-mimicking hydrogels, it is possible to investigate the impact of vaporized PSNE on ultrasound-mediated heating and thermal ablation. Delivery of therapeutic agents and nanoparticles to the tumor core in vivo remains a challenge due to increased interstitial pressures that are found there. It is likely that PSNE would preferentially accumulate within the tumor periphery and may not easily penetrate the tumor core. Studies in hydrogels have shown that bubbles can redirect acoustic energy toward the transducer resulting in ablated volumes in the prefocal region. This phenomenon occurs when the transmitted acoustic power exceeds a specific threshold. Thus, it is possible to localize bubble-enhanced tumor ablation to the tumor periphery using one power setting as well as ablate the inner core by reflecting acoustic energy off bubbles created in distal margin at a higher power setting. Furthermore, precise ablation of the tumor periphery that avoids damaging the surrounding healthy tissue would still represent a significant breakthrough and could potentially allow previously non-resectable tumors to be removed surgically. Although there are differences between in vivo conditions and the tissue-mimicking hydrogels, the phantoms are useful for understanding the physical mechanisms of ultrasound-enhanced heating with PSNE in order to optimize the ultrasound parameters for thermal ablation. These are critical steps for translating the use of PSNE for enhancing ultrasound-mediated ablation from the laboratory to the clinic.