![David Jamieson](https://profiles-cardiff.imgix.net/attachments/2928?w=200&h=200&auto=format&crop=faces&fit=crop&q=90")
Dr David Jamieson
- Available for postgraduate supervision
Teams and roles for David Jamieson
Post Doctoral Research Associate
Overview
I currently hold a postdoctoral position in the group of Dr Oliver Castell where I am using electrophysiological measurements and single molecule imaging to grow projects ranging from the development of photostable environmentally sensitive fluorescent probes to real time imaging of the function and behaviour of protein pores.
Publication
2025
- Ahmed, R. D. et al. 2025. Molecular dynamics guided identification of a brighter variant of superfolder Green Fluorescent Protein with increased photobleaching resistance. Communications Chemistry 8 174. (10.1038/s42004-025-01573-4)
2024
- Dimitriou, P. et al. 2024. Manipulation of encapsulated artificial phospholipid membranes using sub-micellar lysolipid concentrations. Communications Chemistry 7 (1) 120. (10.1038/s42004-024-01209-z)
- Schneider, J. J. et al., 2024. Percolation breakdown in binary and ternary monodisperse and polydisperse systems of spherical particles. Presented at: Italian Workshop on Artificial Life and Evolutionary Computation Venice 6-8 September 2023. Published in: Villani, M. , Cagnoni, S. and Serra, R. eds. Artificial Life and Evolutionary Computation. WIVACE 2023. Vol. 1977.Communications in Computer and Information Science Cham, Switzerland: Springer. , pp.161-174. (10.1007/978-3-031-57430-6_13)
- Schneider, J. J. et al., 2024. Kauffman Model with spatially separated ligation and cleavage reactions. Presented at: Italian Workshop on Artificial Life and Evolutionary Computation Venice 6-8 September 2023. Published in: Villani, M. , Cagnoni, S. and Serra, R. eds. Artificial Life and Evolutionary Computation. WIVACE 2023. Vol. 1977.Communications in Computer and Information Science Cham, Switzerland: Springer. , pp.141-160. (10.1007/978-3-031-57430-6_12)
- Silver, K. L. et al. 2024. 3D-printed microfluidic-microwave device for droplet network formation and characterisation. Lab on a Chip 24 , pp.5101-5112. (10.1039/D4LC00387J)
2022
- Baxani, D. K. et al. 2022. Encapsulated droplet interface bilayers as a platform for high-throughput membrane studies. Soft Matter 18 , pp.5089-5096. (10.1039/D1SM01111A)
- Li, J. et al. 2022. Building programmable multicompartment artificial cells incorporating remotely activated protein channels using microfluidics and acoustic levitation. Nature Communications 13 (1) 4125. (10.1038/s41467-022-31898-w)
2021
- Pope, J. R. et al. 2021. Association of fluorescent protein pairs and it's significant impact on fluorescence and energy transfer. Advanced Science 8 (1) 2003167. (10.1002/advs.202003167)
2020
- Li, J. et al. 2020. Formation of polarised, functional artificial cells from compartmentalised droplet networks and nanomaterials, using one-step, dual-material 3D-printed microfluidics. Advanced Science 7 (1) 1901719. (10.1002/advs.201901719)
- Thomas, S. K. et al. 2020. Site-specific protein photochemical covalent attachment to carbon nanotube side walls and its electronic impact on single molecule function. Bioconjugate Chemistry 31 (3), pp.584-594. (10.1021/acs.bioconjchem.9b00719)
2019
- Worthy, H. L. et al. 2019. Positive functional synergy of structurally integrated artificial protein dimers assembled by Click chemistry. Communications Chemistry 2 83. (10.1038/s42004-019-0185-5)
2018
- Baxani, D. K. et al., 2018. An encapsulated droplet interface bilayer array for the high-throughput optical measurement of lipid membranes with single bilayer resolution. Biophysical Journal 114 (3), pp.686A. (10.1016/j.bpj.2017.11.3699)
2016
- Baxani, D. K. et al., 2016. Bilayer networks within a hydrogel shell: A robust chassis for artificial cells and a platform for membrane studies. Angewandte Chemie International Edition 55 (46), pp.14240-14245. (10.1002/anie.201607571)
- Morgan, A. J. L. et al. 2016. Simple and versatile 3D printed microfluidics using fused filament fabrication. PLoS ONE 11 (4) e0152023. (10.1371/journal.pone.0152023)
Articles
- Ahmed, R. D. et al. 2025. Molecular dynamics guided identification of a brighter variant of superfolder Green Fluorescent Protein with increased photobleaching resistance. Communications Chemistry 8 174. (10.1038/s42004-025-01573-4)
- Baxani, D. K. et al. 2022. Encapsulated droplet interface bilayers as a platform for high-throughput membrane studies. Soft Matter 18 , pp.5089-5096. (10.1039/D1SM01111A)
- Baxani, D. K. et al., 2018. An encapsulated droplet interface bilayer array for the high-throughput optical measurement of lipid membranes with single bilayer resolution. Biophysical Journal 114 (3), pp.686A. (10.1016/j.bpj.2017.11.3699)
- Baxani, D. K. et al., 2016. Bilayer networks within a hydrogel shell: A robust chassis for artificial cells and a platform for membrane studies. Angewandte Chemie International Edition 55 (46), pp.14240-14245. (10.1002/anie.201607571)
- Dimitriou, P. et al. 2024. Manipulation of encapsulated artificial phospholipid membranes using sub-micellar lysolipid concentrations. Communications Chemistry 7 (1) 120. (10.1038/s42004-024-01209-z)
- Li, J. et al. 2020. Formation of polarised, functional artificial cells from compartmentalised droplet networks and nanomaterials, using one-step, dual-material 3D-printed microfluidics. Advanced Science 7 (1) 1901719. (10.1002/advs.201901719)
- Li, J. et al. 2022. Building programmable multicompartment artificial cells incorporating remotely activated protein channels using microfluidics and acoustic levitation. Nature Communications 13 (1) 4125. (10.1038/s41467-022-31898-w)
- Morgan, A. J. L. et al. 2016. Simple and versatile 3D printed microfluidics using fused filament fabrication. PLoS ONE 11 (4) e0152023. (10.1371/journal.pone.0152023)
- Pope, J. R. et al. 2021. Association of fluorescent protein pairs and it's significant impact on fluorescence and energy transfer. Advanced Science 8 (1) 2003167. (10.1002/advs.202003167)
- Silver, K. L. et al. 2024. 3D-printed microfluidic-microwave device for droplet network formation and characterisation. Lab on a Chip 24 , pp.5101-5112. (10.1039/D4LC00387J)
- Thomas, S. K. et al. 2020. Site-specific protein photochemical covalent attachment to carbon nanotube side walls and its electronic impact on single molecule function. Bioconjugate Chemistry 31 (3), pp.584-594. (10.1021/acs.bioconjchem.9b00719)
- Worthy, H. L. et al. 2019. Positive functional synergy of structurally integrated artificial protein dimers assembled by Click chemistry. Communications Chemistry 2 83. (10.1038/s42004-019-0185-5)
Conferences
- Schneider, J. J. et al., 2024. Percolation breakdown in binary and ternary monodisperse and polydisperse systems of spherical particles. Presented at: Italian Workshop on Artificial Life and Evolutionary Computation Venice 6-8 September 2023. Published in: Villani, M. , Cagnoni, S. and Serra, R. eds. Artificial Life and Evolutionary Computation. WIVACE 2023. Vol. 1977.Communications in Computer and Information Science Cham, Switzerland: Springer. , pp.161-174. (10.1007/978-3-031-57430-6_13)
- Schneider, J. J. et al., 2024. Kauffman Model with spatially separated ligation and cleavage reactions. Presented at: Italian Workshop on Artificial Life and Evolutionary Computation Venice 6-8 September 2023. Published in: Villani, M. , Cagnoni, S. and Serra, R. eds. Artificial Life and Evolutionary Computation. WIVACE 2023. Vol. 1977.Communications in Computer and Information Science Cham, Switzerland: Springer. , pp.141-160. (10.1007/978-3-031-57430-6_12)
Research
Overall my interests lie at the interface between microbiology, biophysics, biochemistry infectious disease and healthcare.
I can help you with Microscopy, Matlab, microbiology, CAD and 3D printing among others.
Biography
I undertook my PhD in biophysical chemistry at the University of Bath where I developed fluorescence based nanoscale lipid / polymer biosensors for the rapid detection of bacterial haemolysins. In particular I focused on a group of peptides from S.aureus called phenol soluble modulins.
On completion of my PhD I undertook a position at Public Health England where I worked towards the development of a microfluidic phenotypic assay for the rapid detection of carbapenemases in the ESKAPEE group of bacterial pathogens.
Outside work I like to climb, swim, walk, play video games, code and watch rugby.