Abstract:Chemically and biochemically functionalized colloidal nanoparticles with appropriate surface chemistry are essential for various biomedical applications. Although a variety of approaches are now available in making such functional nanoparticles and nanobioconjugates, the lack of complementary surface chemistry often leads to poor performance with respect to intended biomedical applications. This feature article will focus on our efforts to make colloidal nanobioconjugates with appropriate/complementary surface… Show more
“…As shown in Figure 3D, 1 , 3 , and 5 displayed positive zeta potentials in PBS (pH = 6.5), which might be caused by the protonation of N atoms in COFs. NPs with electropositive zeta potential should be of great benefit to the tumor cell uptake owing to their high affinity for the negatively charged tumor cell membranes (Chakraborty et al., 2018, Intlekofer and Finley, 2019). Figure 3NP Microtopography Characterization(A) Transmission electron microscopic images of 1 , 3 , and 5 .…”
HIGHLIGHTS Covalent organic frameworks (COFs) are first used in tumor photodynamic therapy BODIPY-decorated COFs are synthesized via bonding defects functionalization BODIPY-decorated COFs have excellent anti-tumor efficacy in vitro and in vivo COFs show great promise as nanoplatforms for biomedical applications
“…As shown in Figure 3D, 1 , 3 , and 5 displayed positive zeta potentials in PBS (pH = 6.5), which might be caused by the protonation of N atoms in COFs. NPs with electropositive zeta potential should be of great benefit to the tumor cell uptake owing to their high affinity for the negatively charged tumor cell membranes (Chakraborty et al., 2018, Intlekofer and Finley, 2019). Figure 3NP Microtopography Characterization(A) Transmission electron microscopic images of 1 , 3 , and 5 .…”
HIGHLIGHTS Covalent organic frameworks (COFs) are first used in tumor photodynamic therapy BODIPY-decorated COFs are synthesized via bonding defects functionalization BODIPY-decorated COFs have excellent anti-tumor efficacy in vitro and in vivo COFs show great promise as nanoplatforms for biomedical applications
“…lysosomes, mitochondria and nucleus etc.) via multiple mechanisms (Chakraborty et al, 2018;Wang F. et al, 2019;Yuanjie Zhu and Yuanjie Zhu, 2019;Guo et al, 2020).…”
Section: Current Scenario Of Subcellular Drug Targetingmentioning
confidence: 99%
“…Similarly, another functionalized colloidal nanoparticulate system with chemical and biochemical surface functionalization was developed, which took into account the recent concept of nanoprobes. Polyacrylate material was employed to form colloidal nanoprobes with the specific aim of targeting subcellular compartments such that the nanobioconjugates can facilitate nanoparticle-cell interaction, helping the endocytosis lead to localized subcellular disposition of the active molecule (Chakraborty et al, 2018).…”
Section: Current Scenario Of Subcellular Drug Targetingmentioning
The movement of micro and macro molecules into and within a cell significantly governs several of their pharmacokinetic and pharmacodynamic parameters, thus regulating the cellular response to exogenous and endogenous stimuli. Trafficking of various pharmacological agents and other bioactive molecules throughout and within the cell is necessary for the fidelity of the cells but has been poorly investigated. Novel strategies against cancer and microbial infections need a deeper understanding of membrane as well as subcellular trafficking pathways and essentially regulate several aspects of the initiation and spread of anti-microbial and anti-cancer drug resistance. Furthermore, in order to avail the maximum possible bioavailability and therapeutic efficacy and to restrict the unwanted toxicity of pharmacological bioactives, these sometimes need to be functionalized with targeting ligands to regulate the subcellular trafficking and to enhance the localization. In the recent past the scenario drug targeting has primarily focused on targeting tissue components and cell vicinities, however, it is the membranous and subcellular trafficking system that directs the molecules to plausible locations. The effectiveness of the delivery platforms largely depends on their physicochemical nature, intracellular barriers, and biodistribution of the drugs, pharmacokinetics and pharmacodynamic paradigms. Most subcellular organelles possess some peculiar characteristics by which membranous and subcellular targeting can be manipulated, such as negative transmembrane potential in mitochondria, intraluminal delta pH in a lysosome, and many others. Many specialized methods, which positively promote the subcellular targeting and restrict the off-targeting of the bioactive molecules, exist. Recent advancements in designing the carrier molecules enable the handling of membrane trafficking to facilitate the delivery of active compounds to subcellular localizations. This review aims to cover membrane trafficking pathways which promote the delivery of the active molecule in to the subcellular locations, the associated pathways of the subcellular drug delivery system, and the role of the carrier system in drug delivery techniques.
“…Variety of nanoparticles are used as fluorescent bioimaging probes with specific advantages over molecular probes (Ruedas‐Rama, Walters, Orte, & Hall, ; Vendrell, Zhai, Er, & Chang, ; Zhang, Campbell, Ting, & Tsien, ). These fluorescent nanoprobes are mainly composed of semiconductor quantum dot (Chakraborty, Dalal, & Jana, ; Wegner & Hildebrandt, ), upconversion nanoparticle (Liu, Y., Lu, Y., et al, 2017; Wen et al, ; Wu et al, ), doped semiconductor nanoparticle (Maity et al, ; Yu et al, ), and carbon dot (Ding, Zhu, & Tian, ; Hong, Diao, Antaris, & Dai, ; Misra et al, ). Table summarizes all these nanoprobes with their specific advantages and limitations.…”
Fluorescent carbon dot has emerged as promising alternative of conventionally known quantum dot or molecular probe as potential intracellular imaging probe. In particular, <10 nm size, tunable and bright fluorescence of carbon dot deserve the application potential as intracellular imaging probe. However, synthesis of carbon dot with narrow particle size distribution, preparation of high‐quality red/near‐infrared emitting carbon dot and appropriate design of functional carbon dot for subcellular targeting are most critical issues. This advanced review focus on the application potential of fluorescent carbon dot as intracellular imaging probe. At first, we briefly discuss different types of fluorescent carbon dots and origin of their fluorescence. Next, we focus on surface chemistry and functionalization which are relevant to intracellular probe development. Finally we have summarized various types of intracellular nanoprobes that are developed from fluorescence carbon dot.
This article is categorized under:
Diagnostic Tools > in vitro Nanoparticle‐Based Sensing
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