Oxygen Gas–Filled Microparticles Provide Intravenous Oxygen Delivery

Kheir, John N.; Scharp, Laurie A.; Borden, Mark A.; Swanson, Edward J.; Loxley, Andrew; Reese, James H.; Black, Katherine J.; Velázquez, Luis Ángel; Thomson, Lindsay M.; Walsh, Brian K; Mullen, Kathryn E.; Graham, Dionne A.; Lawlor, Michael W.; Brugnara, Carlo; Bell, David C.; McGowan, Francis X.

doi:10.1126/scitranslmed.3003679

Sci. Transl. Med.

2012

DOI: 10.1126/scitranslmed.3003679

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Oxygen Gas–Filled Microparticles Provide Intravenous Oxygen Delivery

John N. Kheir

Laurie A. Scharp

Mark A. Borden

et al.

Abstract: We have developed an injectable foam suspension containing self-assembling, lipid-based microparticles encapsulating a core of pure oxygen gas for intravenous injection. Prototype suspensions were manufactured to contain between 50 and 90 ml of oxygen gas per deciliter of suspension. Particle size was polydisperse, with a mean particle diameter between 2 and 4 μm. When mixed with human blood ex vivo, oxygen transfer from 70 volume % microparticles was complete within 4 s. When the microparticles were infused b… Show more

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Cited by 102 publications

(119 citation statements)

References 34 publications

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“…One potential solution to this problem is to use a gas-stabilizing agent to contain the oxygen gas and to prevent bubble coalescence during and following injection (16)(17)(18)(19). From a theoretical perspective, this approach is preferred as it overcomes the concentration limits of dissolved or bound oxygen.…”

mentioning

confidence: 99%

“…From a theoretical perspective, this approach is preferred as it overcomes the concentration limits of dissolved or bound oxygen. Our group first demonstrated the feasibility of this approach by packaging oxygen gas within lipid-coated microbubbles (LOMs) (17). Similar to microbubble-based contrast agents, LOMs consist of an oxygen gas core stabilized by a lipid shell.…”

mentioning

confidence: 99%

“…Similar to microbubble-based contrast agents, LOMs consist of an oxygen gas core stabilized by a lipid shell. Oxygen transport across the shell occurs via passive diffusion and is triggered when the bubble encounters blood with low oxygen tensions (i.e., relative to the oxygen-rich LOM core, pO 2 < 740 mmHg) (16)(17)(18). Because LOMs contain large gas volume fractions [i.e., >70% (vol/vol)], they can deliver substantially larger gas payloads than other particle-based systems that use hemoglobin, heme derivatives, or PFCs.…”

mentioning

confidence: 99%

“…In fact, i.v. infusion of LOMs rapidly raised arterial blood saturations and decreased the incidence of death in several animal models of severe hypoxemia (17,20). However, despite the effectiveness of lipid-based stabilizing agents, several challenges must be addressed before clinical translation.…”

mentioning

confidence: 99%

“…First, the fluid nature of lipid shells renders LOMs mechanically fragile and introduces the possibility of rupture during rapid injections, releasing free gas to the bloodstream. Second, LOMs, like other lipid-based carriers, are susceptible to coalescence, Ostwald ripening, and Laplace overpressure during storage (21,22), which leads to significant product loss and undesirable changes in size distributions (17). Design strategies that reduce the risk of free gas release, and improve the drug shelf life while preserving a high oxygen carrying capacity,…”

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confidence: 99%

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Oxygen delivery using engineered microparticles

Seekell

Lock

Peng

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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A continuous supply of oxygen to tissues is vital to life and interruptions in its delivery are poorly tolerated. The treatment of low-blood oxygen tensions requires restoration of functional airways and lungs. Unfortunately, severe oxygen deprivation carries a high mortality rate and can make otherwise-survivable illnesses unsurvivable. Thus, an effective and rapid treatment for hypoxemia would be revolutionary. The i.v. injection of oxygen bubbles has recently emerged as a potential strategy to rapidly raise arterial oxygen tensions. In this report, we describe the fabrication of a polymerbased intravascular oxygen delivery agent. Polymer hollow microparticles (PHMs) are thin-walled, hollow polymer microcapsules with tunable nanoporous shells. We show that PHMs are easily charged with oxygen gas and that they release their oxygen payload only when exposed to desaturated blood. We demonstrate that oxygen release from PHMs is diffusion-controlled, that they deliver approximately five times more oxygen gas than human red blood cells (per gram), and that they are safe and effective when injected in vivo. Finally, we show that PHMs can be stored at room temperature under dry ambient conditions for at least 2 mo without any effect on particle size distribution or gas carrying capacity.hypoxemia | microparticle | oxygen | core-shell | colloids

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confidence: 99%

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confidence: 99%

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confidence: 99%

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confidence: 99%

mentioning

confidence: 99%

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Oxygen delivery using engineered microparticles

Seekell

Lock

Peng

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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Bulk Manufacture of Concentrated Oxygen Gas‐Filled Microparticles for Intravenous Oxygen Delivery

Kheir

Polizzotti

Thomson

et al. 2013

Adv Healthcare Materials

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Self-assembling, concentrated, lipid-based oxygen microparticles (LOMs) have been developed to administer oxygen gas when injected intravenously, preventing organ injury and death from systemic hypoxemia in animal models. Distinct from blood substitutes, LOMs are a one-way oxygen carrier designed to rescue patients who experience life-threatening hypoxemia, as caused by airway obstruction or severe lung injury. Here, we describe methods to manufacture large quantities of LOMs using an in-line, recycling, high-shear homogenizer, which can create up to 4 liters of microparticle emulsion in 10 minutes, with particles containing a median diameter of 0.93 microns and 60 volume% of gas phase. Using this process, we screen 30 combinations of commonly used excipients for their ability to form stable LOMs. LOMs composed of DSPC and cholesterol in a 1:1 molar ratio are stable for a 100 day observation period, and the number of particles exceeding 10 microns in diameter does not increase over time. When mixed with blood in vitro, LOMs fully oxygenate blood within 3.95 seconds of contact, and do not cause hemolysis or complement activation. LOMs can be manufactured in bulk by high shear homogenization, and appear to have a stability and size profile which merit further testing.

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Ultrasound Responsive Noble Gas Microbubbles for Applications in Image‐Guided Gas Delivery

Chattaraj

Hwang

Zemerov

et al. 2020

Adv Healthcare Materials

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Noble gases, especially xenon (Xe), have been shown to have antiapoptotic effects in treating hypoxia ischemia related injuries. Currently, in vivo gas delivery is systemic and performed through inhalation, leading to reduced efficacy at the injury site. This report provides a first demonstration of the encapsulation of pure Xe, Ar, or He in phospholipid‐coated sub‐10 µm microbubbles, without the necessity of stabilizing perfluorocarbon additives. Optimization of shell compositions and preparation techniques show that distearoylphosphatidylcholine (DSPC) with DSPE‐PEG5000 can produce stable microbubbles upon shaking, while dibehenoylphosphatidylcholine (DBPC) blended with either DSPE‐PEG2000 or DSPE‐PEG5000 produces a high yield of microbubbles via a sonication/centrifugation method. Xe and Ar concentrations released into the microbubble suspension headspace are measured using GC‐MS, while Xe released directly in solution is detected by the fluorescence quenching of a Xe‐sensitive cryptophane molecule. Bubble production is found to be amenable to scale‐up while maintaining their size distribution and stability. Excellent ultrasound contrast is observed in a phantom for several minutes under physiological conditions, while an intravenous administration of a bolus of pure Xe microbubbles provides significant contrast in a mouse in pre‐ and post‐lung settings (heart and kidney, respectively), paving the way for image‐guided, localized gas delivery for theranostic applications.

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Oxygen Gas–Filled Microparticles Provide Intravenous Oxygen Delivery

Cited by 102 publications

References 34 publications

Oxygen delivery using engineered microparticles

Oxygen delivery using engineered microparticles

Bulk Manufacture of Concentrated Oxygen Gas‐Filled Microparticles for Intravenous Oxygen Delivery

Ultrasound Responsive Noble Gas Microbubbles for Applications in Image‐Guided Gas Delivery

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