Research Areas - (169) Quantum Biology / Biosensing

Full path: Biology > Biophysics > Quantum Biology / Biosensing

Department(s)/lab(s): Chemistry (Physical and Theoretical Chemistry Laboratory) | Kukura Group @ Oxford
Summary:

Kukura invented mass photometry, a label-free interferometric-scattering microscopy technique that mass-images single biomolecules in solution with precision rivalling native mass spectrometry; his group continues to expand the technique's hardware, analysis (including deep learning) and range of biomolecular applications, in close collaboration with Justin Benesch.

Department(s)/lab(s): School of Physics / Institute of Medical Physics | Kuncic Medical Physics and Nanoscale Systems Group @ USyd
Summary:

Kuncic works across medical physics and nanoscale systems: nanoparticle-enhanced radiotherapy and dosimetry (where high-Z nanoparticles act as local dose amplifiers and the physics question is energy deposition at nanometre scales), nanoparticle contrast agents and theranostics, and — separately — neuromorphic nanowire networks as physical computing substrates. The medical-physics thread is the relevant one here: it is about quantifying and imaging what a nanoscale probe does inside tissue. Positioned against the established body of NV-ensemble quantum sensing work — DEER, nanoscale NMR and T1 relaxometry protocols operating at pT/sqrt(Hz) field sensitivity — the nanoparticle-in-tissue problem she works on is the same delivery-and-quantification problem that determines whether an in-cell nanodiamond sensor operating near the pT/sqrt(Hz) regime reports anything biologically meaningful. Borderline inclusion; a candidate would be bringing quantum sensing to her, not the reverse.

Department(s)/lab(s): Bioengineering | Ladame Biosensors Group @ Imperial
Summary:

Ladame develops biosensors and molecular diagnostic assays that detect cell-free circulating nucleic acid biomarkers (DNA/RNA) directly, without enzymatic amplification, for applications in early disease diagnosis and monitoring.

Department(s)/lab(s): Yusuf Hamied Department of Chemistry | The Lee Lab – Biophysical Chemistry @ Cambridge
Summary:

Lee leads TheLeeLab at Cambridge Chemistry, focused on developing cutting-edge biophysical single-molecule fluorescence methods to answer fundamental biological questions. Two major thrusts: (1) 3D super-resolution microscopy instrument development — the lab pioneered single-molecule light field microscopy (SMLFM) using a microlens array in the back focal plane, achieving ~10× speed improvement over double-helix PSF for volumetric imaging; also develops vortex light field microscopy (VLFM) for simultaneous 25 nm spatial / 3 nm spectral precision; (2) Biological applications — studying T-cell receptor signalling at the nanoscale (distribution of TCRs, microvilli-mediated close contacts), histone assembly during DNA replication and repair in fission yeast, and PSD-95 nanoclusters in mouse brain using 3D SMLM. A job posting (PDRA) was active in 2025 for T-cell imaging work with super-resolution and Fourier light-field microscopy.

Department(s)/lab(s): Physics | Leifer Lab @ Princeton
Summary:

Leifer develops closed-loop optical instrumentation that simultaneously records brain-wide calcium activity and delivers single-neuron optogenetic perturbations in freely moving C. elegans, building functional atlases of signal propagation and studying how whole-brain neural dynamics generate behavior. His group's whole-brain, cellular-resolution imaging in unrestrained animals is a benchmark advanced-microscopy approach for linking neural dynamics to behavior.

Department(s)/lab(s): Biology / Institute of Molecular Biology (IMB) | Lemke Lab - Synthetic Biophysics @ JGU
Summary:

Lemke holds the chair of Synthetic Biophysics at JGU and is adjunct director at the Institute of Molecular Biology. The group's signature is combining genetic code expansion -- installing non-canonical amino acids so a dye can be clicked onto one chosen residue -- with single-molecule fluorescence: smFRET on intrinsically disordered proteins, super-resolution imaging of the nuclear pore complex and its FG-nucleoporin permeability barrier, and engineered membraneless organelles used as designer compartments in living cells. The result is single-molecule-resolution measurement of conformational dynamics and phase behaviour inside cells rather than in vitro. Relative to the established NV-ensemble quantum-sensing playbook (DEER, nanoscale NMR, T1 relaxometry at pT/sqrt(Hz) ensemble sensitivity), this is the strongest biosensing/advanced-microscopy host in Mainz: the labelling chemistry is precisely what a quantum-sensing postdoc would need to attach nanodiamonds or spin labels to a defined protein site, and the group already operates at the single-molecule sensitivity limit optically. Large, well-funded, internationally recruiting group.

Department(s)/lab(s): Molecular and Cellular Biology | Lichtman Lab @ Harvard
Summary:

Lichtman invented the multicolor 'Brainbow' fluorescent labeling method and pioneered large-scale, automated serial-section electron microscopy to reconstruct complete synaptic wiring diagrams (connectomes) of neural tissue, pushing spatial resolution and scale together to map circuit-level brain structure.

Department(s)/lab(s): Electrical Engineering & Computer Sciences | C. Liu MRI Physics Lab @ UCB
Summary:

Liu develops quantitative susceptibility mapping and other advanced magnetic-field-sensitive MRI acquisition and reconstruction methods to noninvasively map brain iron, myelin, and microstructure with a precision that approaches magnetometric sensing of tissue magnetic properties.

Department(s)/lab(s): Bioengineering | Jia Liu Group @ Harvard
Summary:

Liu develops ultra-flexible, tissue-scaffold-integrated mesh bioelectronics that become seamlessly incorporated into developing neural tissue, enabling minimally invasive single-cell recording of brain activity with millisecond precision as the brain develops — a bioelectronic sensing platform explicitly aimed at eventual human/clinical translation for understanding neurodevelopmental disease.

Department(s)/lab(s): Department of Physics, 2nd Institute of Physics | Liu Group - Smart Nanoplasmonics (2. Physikalisches Institut) @ Stuttgart
Summary:

Liu's group sits at the junction of DNA nanotechnology and nanophotonics: DNA-origami-templated plasmonic assemblies, reconfigurable artificial nanomachines whose motion is read out optically (chiral plasmonics, FRET), and, increasingly, synthetic-cell systems -- DNA-based pores and a programmable DNA-origami nanosyringe for directed membrane translocation, the latter published jointly with Nussberger's biophysics group at Stuttgart. The through-line is building nanoscale machines that both actuate and report. Relative to the established NV-ensemble quantum-sensing playbook (DEER, nanoscale NMR, T1 relaxometry at pT/sqrt(Hz) ensemble sensitivity), the relevance is on the biosensing axis: this is the group that can put a nanoscale probe exactly where you want it on or through a membrane, which is the delivery problem that in-cell quantum sensing keeps running into. Preferred-attribute note: nanofabrication is heavily used, but the emphasis is on single-molecule optical readout rather than device manufacture per se.