Micro‐ and Nano‐Devices for Studying Subcellular Biology

Siedlik, Michael J.; Yang, Zijian; Kadam, Parnika; Eberwine, James; Issadore, David

doi:10.1002/smll.202005793

Cited by 18 publications

(21 citation statements)

References 99 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…To address these challenges, a cellular membrane cloaking technique has recently been proposed as a unique surface construction tool from the perspectives of physiology and immunology, demonstrating effectiveness in boosting the in vivo activity of synthesized micro/nanocarriers. 4 Advances in Materials Science and Engineering…”

Section: Biohybrid Micro/nanorobotsmentioning

confidence: 99%

“…ese qualities, when combined, enable the robots to execute a wide range of activities in a variety of fields, such as cell disruption, active medication administration, noninvasive surgical, environment monitoring, and nanoscale manufacturing and monitoring. Only with the rapid growth of micro-and nanodevices in biology and medicine, developing robots with biodegradable and bioinspired interfaces for favorable interactions and interfaces involving basic biological organisms has become critical [4]. Manufactured nanorobots, for instance, have lately been merged into motile organisms including sperm and bacteria.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Nanorobots with Hybrid Biomembranes for Simultaneous Degradation of Toxic Microorganism

Refaai

Manjunatha

Radjarejesri³

et al. 2022

Advances in Materials Science and Engineering

View full text Add to dashboard Cite

Nanorobotics is a modern technological sector that creates robots with elements that are close to or near the nanoscale scale of such a nanometer. To be more specific, nanorobotics has been the nanotechnology approach to designing and creating nanorobots. Also, with the fast growth of robotics technology, developing biomaterials micro- or nanorobots, which convert biological concepts into a robotic device, grows progressively vital. This proposes the development, manufacturing, and testing of a dual–cell membrane–functionalized nanorobot for multifunctional biological threat component elimination, with a focus on the simultaneous targeted and neutralization of the pathogenic bacteria and toxins. Ultrasound-propelled biomaterials nanorobots comprised of the gold nanostructures wrapped in a combination of platelet (PL) and Red Blood Cell (RBC) layers were developed. Biohybrid micro- and nanorobots were small machines that combine biological and artificial elements. They may benefit from onboard actuators, detection, management, and deployment of a variety in medical functions. These hybrid cell walls consist of a variety of structural proteins involved in living organism RBCs and PLs, which provide nanorobots with either a quantity of the appealing biological functionality, with bonding and adhesion to the PL-adhering pathogenic organisms (for example, staphylococcus bacteria) but also neutralization of the pore-forming toxins (e.g., toxin). Furthermore, the biomaterials nanorobots demonstrated quick and efficient extended sonic propulsion for total blood with really no visible bacterial growth and mirrored the movements of genuine cell separation. This propulsion improved the robots’ bonding and detoxifying efficacy against infections and poisons. Overall, combining this diversified physiological activity of hybrid cellular tissue with the energy propulsion of such robotic systems contributed to the dynamic robotics scheme for effective separation and synchronous elimination of various living risks, a significant step towards to development of a broad-spectrum detoxifying robotic framework.

show abstract

Section: Biohybrid Micro/nanorobotsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Nanorobots with Hybrid Biomembranes for Simultaneous Degradation of Toxic Microorganism

Refaai

Manjunatha

Radjarejesri³

et al. 2022

Advances in Materials Science and Engineering

View full text Add to dashboard Cite

show abstract

“…Finally, with the demonstrated robustness, beyond the current COVID-19 pandemic, eSIREN could be further expanded for accessible detection of other infectious diseases and improved patient stratification in resource-limited settings ( Wu et al, 2020 ; Zhu et al, 2019 ). Technical improvements, through the integration of advanced microfluidics ( Morikawa et al, 2020 ; Choi et al, 2019 ; Siedlik et al, 2021 ; Zhao et al, 2019 ) and arrayed sensor configuration ( Lim et al, 2019 ; Jeong et al, 2019 ), could facilitate highly-parallel and large-scale testing.…”

Section: Discussionmentioning

confidence: 99%

Accessible detection of SARS-CoV-2 through molecular nanostructures and automated microfluidics

Zhao

Zhang

Chen

et al. 2021

Biosensors and Bioelectronics

View full text Add to dashboard Cite

Accurate and accessible nucleic acid diagnostics is critical to reducing the spread of COVID-19 and resuming socioeconomic activities. Here, we present an integrated platform for the direct detection of SARS-CoV-2 RNA targets near patients. Termed e lectrochemical s ystem i ntegrating r econfigurable e nzyme-DNA n anostructures ( eSIREN ), the technology leverages responsive molecular nanostructures and automated microfluidics to seamlessly transduce target-induced molecular activation into an enhanced electrochemical signal. Through responsive enzyme-DNA nanostructures, the technology establishes a molecular circuitry that directly recognizes specific RNA targets and catalytically enhances signaling; only upon target hybridization, the molecular nanostructures activate to liberate strong enzymatic activity and initiate cascading reactions. Through automated microfluidics, the system coordinates and interfaces the molecular circuitry with embedded electronics; its pressure actuation and liquid-guiding structures improve not only analytical performance but also automated implementation. The developed platform establishes a detection limit of 7 copies of RNA target per μl, operates against the complex biological background of native patient samples, and is completed in <20 min at room temperature. When clinically evaluated, the technology demonstrates accurate detection in extracted RNA samples and direct swab lysates to diagnose COVID-19 patients.

show abstract

“…Determining these chemical specificities is critical to understand the biological reactions they host, their function(s), as well as for designing new technologies through synthetic biology approaches 4 . Successful investigations have characterized the pH and redox potential (Eh) homeostasis in eukaryotic organelles 5 , mainly through methodologies involving fluorescent dyes or probes and subsequent sample imaging [5][6][7][8][9][10] . Similarly, fluorescent methodologies have been used to quantify and map incorporation of calcium and magnesium in intracellular structures for precipitation of biominerals [10][11][12] .…”

Section: Introductionmentioning

confidence: 99%

“…Determining these chemical specificities is critical to understand the biological reactions they host and their function(s) as well as for designing new technologies through synthetic biology approaches . Successful investigations have characterized the pH and redox potential (Eh) homeostasis in eukaryotic organelles, mainly through methodologies involving fluorescent dyes or probes and subsequent sample imaging. − Similarly, fluorescence methodologies have been used to quantify and map incorporation of calcium and magnesium in intracellular structures for precipitation of biominerals. − However, the spatial resolution of these techniques prevents their use for small bacterial and archaeal organelles that can be as small as 50 nm in diameter or less. Alternative approaches must therefore be defined to constrain local chemical conditions in prokaryotic microorganisms.…”

Section: Introductionmentioning

confidence: 99%