Optical Nanosensor for Intracellular and Intracranial Detection of Amyloid-Beta

Antman‐Passig, Merav; Wong, Eitan; Frost, Georgia; Cupo, Christian; Shah, Janki; Agustinus, Albert; Chen, Ziyu; Mancinelli, Chiara; Kamel, Maikel; Li, Thomas; Jonas, Lauren A.; Li, Yue-Ming; Heller, Daniel A.

doi:10.1021/acsnano.2c00054

Cited by 17 publications

(15 citation statements)

References 109 publications

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“…57 Here, we found that the injection of carbon nanotube sensors directly into the cerebellum results in a local extracellular pool of nanotubes in the brain. Extracellular accumulation of nanotube sensors has been reported following intracranial injections 37 and observed in ex vivo preparations. 35,36,61,62 Following intracerebral injection, the sensor localized in extracellular pools and responded in ASMKO mice by a decrease in the average center wavelength.…”

Section: T H Imentioning

confidence: 98%

Nanoreporter Identifies Lysosomal Storage Disease Lipid Accumulation Intracranially

Antman-Passig,

Yaari,

Goerzen

et al. 2023

Nano Lett.

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Dysregulated lipid metabolism contributes to neurodegenerative pathologies and neurological decline in lysosomal storage disorders as well as more common neurodegenerative diseases. Niemann−Pick type A (NPA) is a fatal neurodegenerative lysosomal storage disease characterized by abnormal sphingomyelin accumulation in the endolysosomal lumen. The ability to monitor abnormalities in lipid homeostasis intracranially could improve basic investigations and the development of effective treatment strategies. We investigated the carbon nanotube-based detection of intracranial lipid content. We found that the near-infrared emission of a carbon nanotube-based lipid sensor responds to lipid accumulation in neuronal and in vivo models of NPA. The nanosensor detected lipid accumulation intracranially in an acid sphingomyelinase knockout mouse via noninvasive near-infrared spectroscopy. This work indicates a tool to improve drug development processes in NPA, other lysosomal storage diseases, and neurodegenerative diseases.

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Section: T H Imentioning

confidence: 98%

Nanoreporter Identifies Lysosomal Storage Disease Lipid Accumulation Intracranially

Antman-Passig,

Yaari,

Goerzen

et al. 2023

Nano Lett.

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“…When a SWCNT is functionalized with versatile surface chemistry including smalls molecules, polymers, or DNA, SWCNT forms specific 3D corona interfaces that enable selective molecular recognition of target analytes (Figure b). , This molecular adsorption instantly changes the bandgap structure of SWCNTs, subsequently inducing variations in wavelength or intensity of fluorescence signal. Versatile constructs of this SWCNT based nanosensor have been designed and synthesized to detect a wide range of biochemical molecules of cells, ranging from small molecules such as ROS to large proteins such as interleukin-6 (IL-6) family cytokines and amyloid-beta, even extending to the plant hormone gibberellin. − The nanosensors for the cellular target analytes are integrated within microchannels in a uniform array using the evaporation induced self-assembly (EISA) based on silane chemistry. ,, In the initial stages of NCC operation, excitation laser sources having visible light wavelength for the SWCNT fluorescence are exposed to the nanosensor array from the bottom side of the channel (Figure a). Each single cell flowing just below the nanosensor array is strongly interacting with nIR fluorescence from the array, where a highly focused propagating beam from the shadow-side of the cell is generated due to constructive interference of the light field, called a photonic nanojet (PNJ). , This PNJ phenomenon focuses light in a manner that treats each single cell as a specialized optical lens reflecting the physical characteristics of each single cell.…”

Section: New Class Of Single Cell Analytic Technology: Nanosensor Che...mentioning

confidence: 99%

Nanosensor Chemical Cytometry: Advances and Opportunities in Cellular Therapy and Precision Medicine

Song,

Tian,

Lee

et al. 2023

ACS Meas. Sci. Au

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With the definition of therapeutics now encompassing transplanted or engineered cells and their molecular products, there is a growing scientific necessity for analytics to understand this new category of drugs. This Perspective highlights the recent development of new measurement science on label-free single cell analysis, nanosensor chemical cytometry (NCC), and their potential for cellular therapeutics and precision medicine. NCC is based on microfluidics integrated with fluorescent nanosensor arrays utilizing the optical lensing effect of a single cell to real-time extract molecular properties and correlate them with physical attributes of single cells. This new class of cytometry can quantify the heterogeneity of the multivariate physicochemical attributes of the cell populations in a completely label-free and nondestructive way and, thus, suggest the vein-to-vein conditions for the safe therapeutic applications. After the introduction of the NCC technology, we suggest the technological development roadmap for the maturation of the new field: from the sensor/chip design perspective to the system/software development level based on hardware automation and deep learning data analytics. The advancement of this new single cell sensing technology is anticipated to aid rich and multivariate single cell data setting and support safe and reliable cellular therapeutics. This new measurement science can lead to data-driven personalized precision medicine.

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“…Single-walled carbon nanotubes (SWCNTs) benefit from unique optical and electronic properties, which render them favorable fluorescent probes for imaging, sensing, and biomedical applications, − owing to their fluorescence in the near-IR range where tissue, blood, and biological samples in general are mostly transparent. − Moreover, SWCNT sensors are stable at room temperature, provide spatiotemporal information, and do not photobleach upon use, unlike many other fluorescent sensors. − The mechanism of SWCNT-based sensors usually relies on tailored functionalization of the nanotube surface, which mediates the interaction with the analyte of interest, such that binding of the target molecule results in a modulation of the emitted fluorescence. − Fluorescent SWCNT sensors were applied for the biosensing of different analytes and enzymes. ,,,,− These range from monitoring progesterone and cortisol in vivo (mice), fibrinogen and insulin in blood and cell culture, , nitroaromatics and pathogens , in vivo (plants), volatiles in the gaseous phase, to enzymatic activity. − …”

Section: Introductionmentioning

confidence: 99%

“… 38 − 41 Fluorescent SWCNT sensors were applied for the biosensing of different analytes and enzymes. 23 , 29 , 31 , 37 , 42 − 50 These range from monitoring progesterone and cortisol in vivo (mice), 31 fibrinogen and insulin in blood and cell culture, 45 , 48 nitroaromatics 29 and pathogens 49 , 51 in vivo (plants), volatiles in the gaseous phase, 52 to enzymatic activity. 53 − 55 …”

Section: Introductionmentioning

confidence: 99%

Monitoring the Activity and Inhibition of Cholinesterase Enzymes using Single-Walled Carbon Nanotube Fluorescent Sensors

2022

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Cholinesterase enzymes are involved in a wide range of bodily functions, and their disruption is linked to pathologies such as neurodegenerative diseases and cancer. While cholinesterase inhibitors are used as drug treatments for diseases such as Alzheimer and dementia at therapeutic doses, acute exposure to high doses, found in pesticides and nerve agents, can be lethal. Therefore, measuring cholinesterase activity is important for numerous applications ranging from the search for novel treatments for neurodegenerative disorders to the on-site detection of potential health hazards. Here, we present the development of a near-infrared (near-IR) fluorescent single-walled carbon nanotube (SWCNT) optical sensor for cholinesterase activity and demonstrate the detection of both acetylcholinesterase and butyrylcholinesterase, as well as their inhibition. We show sub U L–1 sensitivity, demonstrate the optical response at the level of individual nanosensors, and showcase an optical signal output in the 900–1400 nm range, which overlaps with the biological transparency window. To the best of our knowledge, this is the longest wavelength cholinesterase activity sensor reported to date. Our near-IR fluorescence-based approach opens new avenues for spatiotemporal-resolved detection of cholinesterase activity, with numerous applications such as advancing the research of the cholinergic system, detecting on-site potential health hazards, and measuring biomarkers in real-time.

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Optical Nanosensor for Intracellular and Intracranial Detection of Amyloid-Beta

Cited by 17 publications

References 109 publications

Nanoreporter Identifies Lysosomal Storage Disease Lipid Accumulation Intracranially

Nanoreporter Identifies Lysosomal Storage Disease Lipid Accumulation Intracranially

Nanosensor Chemical Cytometry: Advances and Opportunities in Cellular Therapy and Precision Medicine

Monitoring the Activity and Inhibition of Cholinesterase Enzymes using Single-Walled Carbon Nanotube Fluorescent Sensors

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