A biocompatible technique for magnetic field sensing at (sub)cellular scale using Nitrogen-Vacancy centers

Bernardi, Ettore; Traina, P.; Petrini, Giulia; Tchernij, S. Ditalia; Forneris, J.; Pastuović, Željko; Degiovanni, I. P.; Olivero, P.; Genovese, M.

doi:10.1140/epjqt/s40507-020-00088-2

Cited by 6 publications

(5 citation statements)

References 33 publications

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“…Using optomechanical mirror mounts, the laser spot could be moved at sub-millimeter precision to any position on the muscle, with a travel of 2 × 2 cm 2 across the chamber. This represents an improvement over a confocal/inverted widefield microscopy configuration where stimulation is limited only to the centre of the objective field of view 7,41 . We positioned the stimulation laser spot approximately 0.5 mm (Figure 1,b) along the muscle away from the diamond, to ensure we recorded signal propagation in only one direction (towards one end of the muscle).…”

Section: Laser Stimulation and Recordingmentioning

confidence: 99%

Laser stimulation of muscle activity with simultaneous detection using a diamond colour centre biosensor

Troise¹,

Hansen²,

Olsson³

et al. 2021

Preprint

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The detection of physiological activity at the microscopic level is key for understanding the function of biosystems and relating this to physical structure.Current sensing methods often rely on invasive probes to stimulate and detect activity, bearing the risk of inducing damage in the target system. In recent years, a new type of biosensor based on color centers in diamond offers the possibility to passively, noninvasively sense and image living biological systems. Here, we use such a sensor for the in-vitro recording of the local magnetic field generated by tightly focused, high intensity pulsed laser optogenetic neuromuscular stimulation of the extensor digitorum longus muscles. Recordings captured a compound action potential response and a slow signal component which we seek to explain using a detailed model of the biological system. We show that our sensor is capable of recording localized neuromuscular activity from the laser stimulation site without photovoltaic or fluorescence artifacts associated with alternative techniques. Our work represents an important step towards selective induction of localized neurobiological activity while performing passive sensing and imaging with diamond sensors, motivating further research into mapping of neural activity and intra-cellular processes.

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Section: Laser Stimulation and Recordingmentioning

confidence: 99%

Laser stimulation of muscle activity with simultaneous detection using a diamond colour centre biosensor

Troise¹,

Hansen²,

Olsson³

et al. 2021

Preprint

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“…For example, living cells can cause internal temperature changes when responding to environmental changes [1,2], but the temperature changes generated by this process are usually small and brief [3], posing a challenge to temperature measurement technology. In recent years, existing intracellular temperature measurement technologies, such as fluorescent proteins [4], organic dyes [5], and rare earth particles [6], have generally suffered from low measurement accuracy [7], insufficient temporal and spatial resolution, and unstable fluorescence [8]. The method of NV centers in diamond stands out due to its stable physical and chemical properties, good biocompatibility [9,10], and ultra-high sensitivity in electronic spin measurement [11].…”

Section: Introductionmentioning

confidence: 99%

The Optimization of Microwave Field Characteristics for ODMR Measurement of Nitrogen-Vacancy Centers in Diamond

Fan,

Xing,

et al. 2024

Photonics

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A typical solid-state quantum sensor can be developed based on negatively charged nitrogen-vacancy (NV−) centers in diamond. The electron spin state of NV− can be controlled and read at room temperature. Through optical detection magnetic resonance (ODMR) technology, temperature measurement can be achieved at the nanoscale. The key to ODMR technology is to apply microwave resonance to manipulate the electron spin state of the NV−. Therefore, the microwave field characteristics formed near the NV− have a crucial impact on the sensitivity of ODMR measurement. This article mainly focuses on the temperature situation in cellular applications and simulates the influence of structural parameters of double open loop resonant (DOLR) microwave antennas and broadband large-area (BLA) microwave antennas on the microwave field’s resonance frequency, quality factor Q, magnetic field strength, uniformity, etc. The parameters are optimized to have sufficient bandwidth, high signal-to-noise ratio, low power loss, and high magnetic field strength in the temperature range of 36 °C to 42.5 °C. Finally, the ODMR spectra are used for effect comparison, and the signal-to-noise ratio and Q values of the ODMR spectra are compared when using different antennas. We have provided an optimization method for the design of microwave antennas and it is concluded that the DOLR microwave antenna is more suitable for living cell temperature measurement in the future.

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“…Considering ODMR measurements on NV ensembles, nanodiamonds present a lower sensitivity compared to bulk diamonds, because of their shorter coherence time (as already mentioned), the lower density of their color centers, and the difficulty in taking advantage of the field alignment [ 39 ] and laser polarization [ 40 ]. On the contrary, a bulk diamond allows ODMR measurements with micrometric spatial resolution on the x-y plane using a focused laser beam and nanometric resolution along the z-direction using a diamond with a thin layer of NV centers [ 41 ]. Furthermore, a bulk diamond can be nanostructured to form an array of diamond nanopillars, leading to the possibility of guiding the growth of the cell network [ 42 ] and to further improvements in sensitivity due to the pillars acting as optical waveguides [ 43 ].…”

Section: Introductionmentioning

confidence: 99%

Limitations of Bulk Diamond Sensors for Single-Cell Thermometry

Alessio,

Bernardi,

Moreva

et al. 2023

Sensors

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The present paper reports on a Finite Element Method (FEM) analysis of the experimental situation corresponding to the measurement of the temperature variation in a single cell plated on bulk diamond by means of optical techniques. Starting from previous experimental results, we have determined—in a uniform power density approximation and under steady-state conditions—the total heat power that has to be dissipated by a single cell plated on a glassy substrate in order to induce the typical maximum temperature increase ΔTglass=1 K. While keeping all of the other parameters constant, the glassy substrate has been replaced by a diamond plate. The FEM analysis shows that, in this case, the maximum temperature increase is expected at the diamond/cell interface and is as small as ΔTdiam=4.6×10−4 K. We have also calculated the typical decay time in the transient scenario, which resulted in τ≈ 250 μs. By comparing these results with the state-of-the-art sensitivity values, we prove that the potential advantages of a longer coherence time, better spectral properties, and the use of special field alignments do not justify the use of diamond substrates in their bulk form.

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A biocompatible technique for magnetic field sensing at (sub)cellular scale using Nitrogen-Vacancy centers

Cited by 6 publications

References 33 publications

Laser stimulation of muscle activity with simultaneous detection using a diamond colour centre biosensor

Laser stimulation of muscle activity with simultaneous detection using a diamond colour centre biosensor

The Optimization of Microwave Field Characteristics for ODMR Measurement of Nitrogen-Vacancy Centers in Diamond

Limitations of Bulk Diamond Sensors for Single-Cell Thermometry

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