Evaluating differential nanoparticle accumulation and retention kinetics in a mouse model of traumatic brain injury via Ktrans mapping with MRI

Miller, Hunter A.; Magsam, Alexander W.; Tarudji, Aria W.; Romanova, Svetlana; Weber, Laura; Gee, Connor C.; Madsen, Gary L.; Bronich, Tatiana K.; Kievit, Forrest M.

doi:10.1038/s41598-019-52622-7

Cited by 24 publications

(38 citation statements)

References 46 publications

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“…This effect may be due to the reduced accumulation of neutral, negative, and zwitterionic peptide-modified nanoparticles in off-target organs (Figure 5a ) and improved blood retention when compared to R9- and K9-modified nanoparticles (Figure 4b ). Previous research supports increased nanomaterial blood half-life with increased passive injury accumulation in TBI models due to the EPR-like effect in the injured tissue ( 11 , 26 , 75 ). Nanomaterials engineered to have long blood half-lives, such as PEG-modified materials, are also well-established nanomedicine platforms in cancer research due to their greater passive accumulation in solid tumors ( 65 , 66 ).…”

Section: Discussionmentioning

confidence: 63%

Pharmacokinetic Analysis of Peptide-Modified Nanoparticles with Engineered Physicochemical Properties in a Mouse Model of Traumatic Brain Injury

Waggoner

Madias

Hurtado

et al. 2021

AAPS J

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Peptides are used to control the pharmacokinetic profiles of nanoparticles due to their ability to influence tissue accumulation and cellular interactions. However, beyond the study of specific peptides, there is a lack of understanding of how peptide physicochemical properties affect nanoparticle pharmacokinetics, particularly in the context of traumatic brain injury (TBI). We engineered nanoparticle surfaces with peptides that possess a range of physicochemical properties and evaluated their distribution after two routes of administration: direct injection into a healthy mouse brain and systemic delivery in a mouse model of TBI. In both administration routes, we found that peptide-modified nanoparticle pharmacokinetics were influenced by the charge characteristics of the peptide. When peptide-modified nanoparticles are delivered directly into the brain, nanoparticles modified with positively charged peptides displayed restricted distribution from the injection site compared to nanoparticles modified with neutral, zwitterionic, or negatively charged peptides. After intravenous administration in a TBI mouse model, positively charged peptide-modified nanoparticles accumulated more in off-target organs, including the heart, lung, and kidneys, than zwitterionic, neutral, or negatively charged peptide-modified nanoparticles. The increase in off-target organ accumulation of positively charged peptide-modified nanoparticles was concomitant with a relative decrease in accumulation in the injured brain compared to zwitterionic, neutral, or negatively charged peptide-modified nanoparticles. Understanding how nanoparticle pharmacokinetics are influenced by the physicochemical properties of peptides presented on the nanoparticle surface is relevant to the development of nanoparticle-based TBI therapeutics and broadly applicable to nanotherapeutic design, including synthetic nanoparticles and viruses. Graphical abstract

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Section: Discussionmentioning

confidence: 63%

Pharmacokinetic Analysis of Peptide-Modified Nanoparticles with Engineered Physicochemical Properties in a Mouse Model of Traumatic Brain Injury

Waggoner

Madias

Hurtado

et al. 2021

AAPS J

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“…On blast-induced TBI mouse model, BBB opening in the acute period was ∼70 kDa (hydrodynamic diameters ∼10 nm), followed by recovery of BBB integrity by 1 day post-injury 138 . On controlled cortical impact model, selective influx of 82 nm PEG-liposomes was found at 0–8 h after injury 128 , and both 20 and 40 nm PEGylated polystyrene NPs accumulated significantly in the injury penumbra up to 13 h after injury 75 , 139 . On diffuse TBI model, PEGylated polystyrene NPs failed to accumulate in the brain tissue after mild closed-head injury 140 .…”

Section: Diseased Bbb-based Brain-targeting Delivery Strategiesmentioning

confidence: 96%

“…The release of intracellular contents from disrupted neurons and the influx of blood components cause secondary injury including ionic imbalance, cytotoxicity, free radical production, oxidative stress, inflammation and further BBB breakdown. These responses lead to vasogenic/osmotic edema for hours and days, resulting in lifelong physical, cognitive and psychosocial impairments 74 , 75 . The primary injury appears to be irreversible, making the focus of therapeutic strategies on neuroprotective approaches that suppress progressive cell death and tissue damages during the secondary injury 74 .…”

Section: Normal Bbb and Diseased Bbbmentioning

confidence: 99%

Evolution of blood–brain barrier in brain diseases and related systemic nanoscale brain-targeting drug delivery strategies

Han

Jiang

2021

Acta Pharmaceutica Sinica B

169

105

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Blood–brain barrier (BBB) strictly controls matter exchange between blood and brain, and severely limits brain penetration of systemically administered drugs, resulting in ineffective drug therapy of brain diseases. However, during the onset and progression of brain diseases, BBB alterations evolve inevitably. In this review, we focus on nanoscale brain-targeting drug delivery strategies designed based on BBB evolutions and related applications in various brain diseases including Alzheimer's disease, Parkinson's disease, epilepsy, stroke, traumatic brain injury and brain tumor. The advances on optimization of small molecules for BBB crossing and non-systemic administration routes ( e . g ., intranasal treatment) for BBB bypassing are not included in this review.

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“…This would limit the quantitative reliability of T1 weighted imaging for IONPs in vivo. Considering the potential benefits of longitudinal studies, there have been efforts to utilize quantitative T1 mapping of the effects of IONPs in rodent studies 41 , 42 . The T1 (or R1) mapping provided objective quantification of IONPs induced R1 (= 1/T1) enhancement.…”

Section: Discussionmentioning

confidence: 99%

Sensitive detection of extremely small iron oxide nanoparticles in living mice using MP2RAGE with advanced image co-registration

Kim

Dodd

et al. 2021

Sci Rep

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Magnetic resonance imaging (MRI) is a widely used non-invasive methodology for both preclinical and clinical studies. However, MRI lacks molecular specificity. Molecular contrast agents for MRI would be highly beneficial for detecting specific pathological lesions and quantitatively evaluating therapeutic efficacy in vivo. In this study, an optimized Magnetization Prepared—RApid Gradient Echo (MP-RAGE) with 2 inversion times called MP2RAGE combined with advanced image co-registration is presented as an effective non-invasive methodology to quantitatively detect T1 MR contrast agents. The optimized MP2RAGE produced high quality in vivo mouse brain T1 (or R1 = 1/T1) map with high spatial resolution, 160 × 160 × 160 µm3 voxel at 9.4 T. Test–retest signal to noise was > 20 for most voxels. Extremely small iron oxide nanoparticles (ESIONPs) having 3 nm core size and 11 nm hydrodynamic radius after polyethylene glycol (PEG) coating were intracranially injected into mouse brain and detected as a proof-of-concept. Two independent MP2RAGE MR scans were performed pre- and post-injection of ESIONPs followed by advanced image co-registration. The comparison of two T1 (or R1) maps after image co-registration provided precise and quantitative assessment of the effects of the injected ESIONPs at each voxel. The proposed MR protocol has potential for future use in the detection of T1 molecular contrast agents.

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Evaluating differential nanoparticle accumulation and retention kinetics in a mouse model of traumatic brain injury via Ktrans mapping with MRI

Cited by 24 publications

References 46 publications

Pharmacokinetic Analysis of Peptide-Modified Nanoparticles with Engineered Physicochemical Properties in a Mouse Model of Traumatic Brain Injury

Pharmacokinetic Analysis of Peptide-Modified Nanoparticles with Engineered Physicochemical Properties in a Mouse Model of Traumatic Brain Injury

Evolution of blood–brain barrier in brain diseases and related systemic nanoscale brain-targeting drug delivery strategies

Sensitive detection of extremely small iron oxide nanoparticles in living mice using MP2RAGE with advanced image co-registration

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