Browse the toolkit beneath workflows. The mechanism branch runs mechanism -> architecture -> component, while the technique branch runs from high-level approaches down to concrete methods.
6 items matching 1 filter
Mechanism Branch
Layer 1
Mechanisms
Top-level concepts: biophysical action modes such as heterodimerization, photocleavage, or RNA binding.
Layer 2
Architectures
Arrangements that realize or deploy mechanisms, including switches, construct patterns, and delivery strategies.
Layer 3
Components
Low-level parts and sequence-defined elements used inside architectures, including protein domains and RNA elements.
Technique Branch
Layer 1
Approaches
High-level engineering practices such as computational design, directed evolution, sequence verification, and functional assay.
Layer 2
Methods
Concrete methods used to design, build, verify, or characterize engineered systems.
Showing 1-6 of 6
Recent technological innovations, including ... super-resolution and photoacoustic imaging ... have created new opportunities for investigating the cellular and molecular basis of VDs.
nanoCRISPR is a light-responsive genome-editing nanosystem composed of a cationic polymer-coated gold nanorod (APC) and a Cas9 plasmid driven by a heat-inducible promoter. It is designed to couple near-infrared photothermal stimulation to regulated Cas9 expression for programmable genome editing.
Here, we report the development of a near-infrared (NIR)-responsive theranostic nanoplatform based on archaeal lipid-derived nanoarchaeosomes (NA) co-encapsulating cisplatin (Cis) and PEGylated gold nanorods (AuNRs), forming a multifunctional NA-Cis-AuNRs nanoformulation.
Here, we report the development of a near-infrared (NIR)-responsive theranostic nanoplatform based on archaeal lipid-derived nanoarchaeosomes (NA)... Archaeal lipids confer robust colloidal stability to this complex, enabling high drug-loading efficiency.
Here we introduce a novel concept of photoswitchable hybrid probes consisting of thermochromic dye and absorbing nanoparticles... Our results suggest that these new photoswitchable multicolour probes can be used for multimodal cellular diagnostics and potentially for magnetic and photothermal therapy.
Among the various strategies for AD treatment, phototherapy, including photothermal therapy (PTT), photodynamic therapy (PDT), and photoresponsive release systems have attracted increased attention because of the spatiotemporal controllability.