Interrogating Amyloid Aggregates using Fluorescent Probes

Aliyan, Amir; Cook, Nathan P.; Martí, Ángel A.

doi:10.1021/acs.chemrev.9b00404

Cited by 209 publications

(202 citation statements)

References 198 publications

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“…Our design strategy is different from most previous studies, which are focused on adjusting optical properties to turn on (off) signals or make larger stokes shis. [9][10][11][12][13] Unfortunately, few probes have been designed based on the insights from the Ab structures. In this report, we demonstrated that our designed small-molecule uorescence probe, ICTAD-1, has the capacity to spectrally differentiate Ab40 and Ab42 in vitro and in the biologically relevant environment.…”

Section: Introductionmentioning

confidence: 99%

Differentiating Aβ40 and Aβ42 in amyloid plaques with a small molecule fluorescence probe

et al. 2020

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Section: Introductionmentioning

confidence: 99%

Differentiating Aβ40 and Aβ42 in amyloid plaques with a small molecule fluorescence probe

et al. 2020

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“…Well‐known examples are Alzheimer's, Parkinson's and Huntington's diseases [2] . To better understand diseases and design drugs, a variety of methods—from biochemical assays to time‐resolved microscopy—have been developed to investigate protein folding [3] and to monitor the self‐assembly of defective proteins into pathogenic protein aggregates [4] . Among them, photoluminescence techniques are highly valuable due to their high sensitivity and the possibility to select, synthesize and optimize a diversity of photoluminescence probes (luminophores).…”

Section: Figurementioning

confidence: 99%

Self‐Reporting of Folding and Aggregation by Orthogonal Hantzsch Luminophores Within a Single Polymer Chain

et al. 2020

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Self‐reporting fluorescence methods for monitoring folding and aggregation of proteins have a long history in biochemistry. Placing orthogonal luminophores within individual synthetic polymer chains for self‐reporting both folding (i.e., its intramolecular compaction to isolated single‐chain nanoparticles, SCNPs) and unbidden aggregation (i.e., the intermolecular association of SCNPs) remains a great challenge. Herein, a simple and efficient platform to identify both single‐chain compaction and intermolecular aggregation phenomena via photoluminescence is presented based on simultaneous synthesis through Hantzsch ester formation of orthogonal luminophores within the same polymer chain. Starting from non‐luminescent β‐ketoester‐decorated chains, intramolecular compaction is visually detected through fluorescence arising from Hantzsch fluorophores generated as intra‐chain connectors during folding. Complementary, intermolecular association is identified via aggregation‐induced emission (AIE) from orthogonal luminophores displaying intense photoluminescence at redshifted wavelengths after formation of multi‐SCNPs assemblies.

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“…Based on the analysis above, we sort out four main criteria which should be satisfied to realize high-performance fluorescent probes for detecting and imaging Aβ fibrils and plaques in vivo at an early stage (Scheme 1B): (1) geometric configurations matching the β-sheet structure; (2) balanced hydrophilicity and hydrophobicity which guarantees the BBB crossing ability and high SNR;…”

Section: Introductionmentioning

confidence: 99%

Rationally Designing Simple Rod-Like Amphiphilic NIR-Emissive AIE Probes for Precise In-Vivo Detection of Aβ Fibrils/Plaques at A Super-Early Stage

Wang¹,

Mei²,

Zhang³

et al. 2021

Preprint

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With increase of social aging, Alzheimer's disease (AD) has been one of the serious diseases threatening human health. The occurrence of Aβ fibrils or plaques is recognized as the hallmark of AD. Currently, optical imaging has stood out to be a promising technique for the imaging of Aβ fibrils/plaques and the diagnosis of AD. However, restricted by their poor blood-brain barrier (BBB) penetrability, short-wavelength excitation and emission, and aggregation-caused quenching (ACQ) effect, the clinically used gold-standard optical probes such as <a>thioflavin</a> T (ThT) and thioflavin S (ThS), are not effective enough in the early diagnosis of AD in vivo. Herein, we put forward an “all-in-one” design principle and demonstrate its feasibility in developing high-performance fluorescent probes which are specific to Aβ fibrils/plaques and promising for super-early in-vivo diagnosis of AD. As a proof of concept, a simple rod-like amphiphilic NIR fluorescent AIEgen, i.e., AIE-CNPy-AD, is developed by taking the specificity, BBB penetration ability, deep-tissue penetration capacity, high signal-to-noise ratio (SNR) into consideration. AIE-CNPy-AD is constituted by connecting the electron-donating and accepting moieties through single bonds and tagging with a propanesulfonate tail, giving rise to the NIR fluorescence, aggregation-induced emission (AIE) effect, amphiphilicity, and rod-like structure, which in turn result in high binding-affinity and excellent specificity to Aβ fibrils/plaques, satisfactory ability to penetrate BBB and deep tissues, ultrahigh SNR and sensitivity, and high-fidelity imaging capability. In-vitro, ex-vivo, and in-vivo <a>identifying of Aβ fibrils/plaques</a> in different strains of mice indicate that AIE-CNPy-AD holds the universality to the detection of Aβ fibrils/plaques. It is noteworthy that AIE-CNPy-AD is even able to trace the small and sparsely distributed Aβ fibrils/plaques in very young AD model mice such as 4-month-old APP/PS1 mice which are reported to be the youngest mice to have Aβ deposits in brains, suggesting its great potential in diagnosis and intervention of AD at a super-early stage.

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Interrogating Amyloid Aggregates using Fluorescent Probes

Cited by 209 publications

References 198 publications

Differentiating Aβ40 and Aβ42 in amyloid plaques with a small molecule fluorescence probe

Differentiating Aβ40 and Aβ42 in amyloid plaques with a small molecule fluorescence probe

Self‐Reporting of Folding and Aggregation by Orthogonal Hantzsch Luminophores Within a Single Polymer Chain

Rationally Designing Simple Rod-Like Amphiphilic NIR-Emissive AIE Probes for Precise In-Vivo Detection of Aβ Fibrils/Plaques at A Super-Early Stage

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