Metallic Nanoislands on Graphene for Biomechanical Sensing

Ramírez, Julián; Polat, Beril; Lipomi, Darren J.

doi:10.1021/acsomega.0c01967

Cited by 7 publications

(3 citation statements)

References 29 publications

(65 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…By transducing swelling into simple DC resistance measurements, we can rapidly assess the swelling mechanics of multiple tissue explants in parallel (Figure c). Strain sensors are made from evaporating palladium nanoislands on a single layer of graphene and can measure strains as low as 0.001%, making them ideal for biomechanical sensing applications. − This high sensitivity at low strains is made possible by swelling strain-induced scattering between the discrete metallic nanoislands patterned on the strain sensors , (Figure d).…”

Section: Experimental Methods and Approachmentioning

confidence: 99%

Optics-Free, In Situ Swelling Monitoring of Articular Cartilage with Graphene Strain Sensors

Sundar

Linardi

Gaesser

et al. 2023

ACS Biomater. Sci. Eng.

View full text Add to dashboard Cite

Articular cartilage derives its load-bearing strength from the mechanical and physiochemical coupling between the collagen network and negatively charged proteoglycans, respectively. Current disease modeling approaches and treatment strategies primarily focus on cartilage stiffness, partly because indentation tests are readily accessible. However, stiffness measurements via indentation alone cannot discriminate between proteoglycan degradation versus collagen degradation, and there is a lack of methods to monitor physiochemical contributors in full-stack tissue. To decouple these contributions, here, we developed a platform that measures tissue swelling in full-depth equine cartilage explants using piezoresistive graphene strain sensors. These piezoresistive strain sensors are embedded within an elastomer bulk and have sufficient sensitivity to resolve minute, real-time changes in swelling. By relying on simple DC resistance measurements over optical techniques, our platform can analyze multiple samples in parallel. Using these devices, we found that cartilage explants under enzymatic digestion showed distinctive swelling responses to a hypotonic challenge and established average equilibrium swelling strains in healthy cartilage (4.6%), cartilage with proteoglycan loss (0.5%), and in cartilage with both collagen and proteoglycan loss (−2.6%). Combined with histology, we decoupled the pathologic swelling responses as originating either from reduced fixed charge density or from loss of intrinsic stiffness of the collagen matrix in the superficial zone. By providing scalable and in situ monitoring of cartilage swelling, our platform could facilitate regenerative medicine approaches aimed at restoring osmotic function in osteoarthritic cartilage or could be used to validate physiologically relevant swelling behavior in synthetic hydrogels.

show abstract

Section: Experimental Methods and Approachmentioning

confidence: 99%

Optics-Free, In Situ Swelling Monitoring of Articular Cartilage with Graphene Strain Sensors

Sundar

Linardi

Gaesser

et al. 2023

ACS Biomater. Sci. Eng.

View full text Add to dashboard Cite

show abstract

“…Unlike traditional fabrication methods such as electron beam lithography or focused ion beam, nanoisland structures can be mass-produced through a simple process of thin film deposition and temperature annealing. This versatility has led to their widespread use in various applications such as enhanced surface plasmon resonance (SPR) detection [1][2][3][4][5][6][7][8][9][10], localization microscopy [11,12], biological sensing [13][14][15][16][17], Raman signal enhancement [18][19][20][21][22][23][24], resonance energy transfer [25,26], and fluorescence and photoluminescence switching [27][28][29][30][31].…”

Section: Introductionmentioning

confidence: 99%

Wide-field nanoscale imaging via near-field speckle illumination by nanoisland substrates

Yoo

Lee

Rhee

et al. 2023

Nanoscale Imaging, Sensing, and Actuation for Biomedical Applications XX

View full text Add to dashboard Cite

Various plasmonic nanostructure-based substrates are used to detect biological signals beyond the diffraction limit with a high signal-to-noise ratio. These approaches take advantage of excitation of localized surface plasmon to acquire highfrequency biological signals while preserving photon energy. Numerous techniques, including focused ion beam, electronbeam lithography, and reactive ion etching, have been used to fabricate plasmonic substrates. However, these fabrication techniques are time and resource-consuming. In contrast, disordered nanostructure-based substrates have attracted interests due to the easy fabrication steps and potential cost savings. Metallic nanoisland substrates, for instance, can be massproduced using thin film deposition and annealing without lithographic process. In this work, we have investigated nanospeckle illumination microscopy (NanoSIM) using disordered near-field speckle illumination generated by nanoisland substrate. Selectively activated fluorescence wide-field images were obtained by nanospeckle illumination generated on the nanoisland substrate. Super-resolved fluorescence images were reconstructed by an optimization algorithm based on blind structured illumination microscopy. Experimental studies of various biological targets including HeLa cell membranes were performed to demonstrate the performance of NanoSIM. Using NanoSIM, we were able to improve spatial resolution of ganglioside distribution in HeLa cells targeted by CT-B by more than threefold compared to the diffraction-limited images. Note that the accessibility of super-resolution imaging techniques can be enhanced by the nanospeckle illumination of disordered metallic nanoislands. These results may be used in imaging and sensing systems that work with detecting biological signals beyond diffraction limits in various applications.

show abstract

“…The core processes rapidly fabricate nanoisland substrates in mass‐production. For this reason, the nanoisland substrates have been explored widely, e.g., for applications in biological sensing, [ 18–21 ] Raman signal enhancement, [ 22–28 ] spontaneous light emission, [ 29 ] resonant energy transfer, [ 30,31 ] solar cells, [ 32,33 ] fluorescence and photoluminescence switching, [ 34–38 ] localization microscopy, [ 39,40 ] light‐emitting diodes, [ 41 ] and broadband photodetectors. [ 42 ] Nanoisland substrates were also used for enhanced surface plasmon resonance (SPR) detection [ 43–53 ] and to investigate its theoretical sensitivity limit.…”

Section: Introductionmentioning

confidence: 99%

Disordered Nanocomposite Islands for Nanospeckle Illumination Microscopy in Wide‐Field Super‐Resolution Imaging

Yoo

Lee

Rhee

et al. 2021

Advanced Optical Materials

View full text Add to dashboard Cite

Nanospeckle illumination microscopy (NanoSIM) based on disordered metallic nanocomposite island substrates is described. The nanoisland substrates can be fabricated without lithographic techniques. Azimuthal scanning illumination of nanoislands creates near‐field distribution that excites an arbitrary number of basis images to produce super‐resolution. Experimental studies of point‐spread images using NanoSIM with 360 basis images obtained by azimuthal scanning find spatial resolution improved by more than three times with an achievable full‐width‐at‐half‐maximum at 81.1 nm on average. The approach is confirmed by imaging aggregated nanobeads and nanoscale distribution of gangliosides on the HeLa cell membrane.

show abstract

Metallic Nanoislands on Graphene for Biomechanical Sensing

Cited by 7 publications

References 29 publications

Optics-Free, In Situ Swelling Monitoring of Articular Cartilage with Graphene Strain Sensors

Optics-Free, In Situ Swelling Monitoring of Articular Cartilage with Graphene Strain Sensors

Wide-field nanoscale imaging via near-field speckle illumination by nanoisland substrates

Disordered Nanocomposite Islands for Nanospeckle Illumination Microscopy in Wide‐Field Super‐Resolution Imaging

Contact Info

Product

Resources

About