Dr David Alexander Gregory
PhD, MSc, BSc, BSc, FHEA
School of Chemical, Materials and Biological Engineering
Lecturer (Assistant Professor)
+44 114 222 7504
Full contact details
School of Chemical, Materials and Biological Engineering
F56
Sir Robert Hadfield Building
Mappin Street
91直播
S1 3JD
- Profile
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David joined the Department of Chemical and Biological Engineering (CBE) in 2023 as a Lecturer. His research is focused on the development of sensing devices for a wide variety of applications including process, medical, and environmental monitoring challenges. An important component of this work is the development of new technologies that enable the fabrication of these devices. Recently, together with collaborators Jonathan Foster (Chemistry) and Patrick Smith (Mechanical Engineering), David has begun developing Reactive Inkjet Printing (RIJ) for multivariate metal organic framework (MOF) gradients, which is hoped can be utilised for advanced sensors.
David has had a fundamental role in the development of RIJ. In the course of this work he designed, built and developed different Reactive Inkjet Printers including both hardware and software, while he has also developed several modifications to existing printing systems to help promote his research. He remains keen to further expand the development of novel printing technologies.
Further to this David is CTO (Chief Technology Officer) in , which promises to become a spin off next year, and is focused on the sustainable production of biocompatible, biodegradable polymers produced via bacterial fermentation. The PHAsT team has recently successfully conducted 100L fermentations with exceptionally high polymer yields at the University of Cambridge facilities, as showcased on their .
David has also gained work experience in the pharmaceutical industry at and in Germany, working in the Departments of Medicinal Chemistry, Enzyme Research, and Drug Formulation Development.
Prior to his present position, he was senior postdoctoral research associate (PDRA) to Prof Roy in the Department of Materials Science and Engineering (MSE) at 91直播 University. This post involved the production of natural polymers via bacterial fermentation for biomedical applications as well as the optimisation and development of novel additive manufacturing processes for material processing and tissue scaffold development. In one of the projects multi-material cardiac patches were successfully developed that are currently being tested in vivo.
Having completed undergraduate degrees in Physics with Astrophysics and Cosmology at and Biochemistry and Music at David went on to study a Masters in Bionanotechnology run jointly between the University of 91直播 and . He then joined the Department of Chemical and Biological Engineering for his PhD on catalytic micromotors, under the supervision of Dr Ebbens, which he completed in 2016.
During this time, David was key for the development of RIJ and enzyme powered silk microrockets, which gained considerable media interest and resulted in several high-quality publications and has consequently resulted in him being invited to speak at several national and international conferences.
Thereafter, he worked as a Postdoctoral Research Associate in CBE further developing his work on RIJ of silk materials, which also resulted in the award of two research grants to his PIs, before he moved as senior PDRA to the MSE Department.
- Research interests
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David is interested in developing novel multidisciplinary projects targeted toward biosensor, bioelectronic, biomedical, regenerative medicine and industrial applications (e.g. process monitoring).
Keywords:
- Sensors / Biosensors
- Raman spectroscopy as a sensing tool
- Additive Manufacturing / 3D Printing
- Reactive Inkjet Printing (RIJ)
- Design and development of complex printing systems
- Biomaterials
- Tissue engineering / 3D scaffolds
- Drug delivery
- Bioelectronics
- Active colloids / micromotors
- Publications
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Journal articles
- . Journal of the Mechanical Behavior of Biomedical Materials, 106722-106722.
- . International Journal of Biological Macromolecules, 134774-134774.
- . ACS Biomaterials Science & Engineering, 9(3), 1472-1485.
- . Advances in Colloid and Interface Science, 314, 102866-102866.
- . Journal of Functional Biomaterials, 14(1).
- . Trends in Molecular Medicine, 28(4), 331-342.
- . JCIS Open, 5.
- . Journal of Colloid and Interface Science, 603, 380-390.
- . Materials Advances, 2(21), 7045-7053.
- . Materials Science and Engineering: R: Reports, 145.
- . Frontiers in Bioengineering and Biotechnology, 9.
- . International Journal of Molecular Sciences, 22(3).
- . Progress in Natural Science: Materials International, 30(5), 686-696.
- . Frontiers in Cardiovascular Medicine, 7.
- . Journal of Visualized Experiments(146).
- . Small, 15(1).
- . International Journal of Pharmaceutics , 555, 322-336.
- . Nanomaterials, 8(11).
- . Accounts of Chemical Research, 51(9), 1931-1939.
- . Langmuir, 34(14), 4307-4313.
- . Small, 12(30), 4048-4055.
- . Journal of Physical Chemistry C, 119(27), 15339-15348.
- . EPL (Europhysics Letters), 106(5).
- . Macromolecular Bioscience.
- . Advanced Materials Interfaces.
- . Journal of Visualized Experiments(146).
- . NIP & Digital Fabrication Conference, 32(1), 452-456.
Chapters
- , The Handbook of Polyhydroxyalkanoates (pp. 255-284). CRC Press
- , Soft, Hard, and Hybrid Janus Structures (pp. 315-403). WORLD SCIENTIFIC (EUROPE)
- , Reactive Inkjet Printing (pp. 169-201). Royal Society of Chemistry
Conference proceedings papers
- BIOINSPIRED NERVE GUIDANCE CONDUITS FOR OPTIMAL NERVE REGENERATION USING POLYHYDROXYALKANOATES. TISSUE ENGINEERING PART A, Vol. 29(11-12) (pp 1404-1404)
- Tissue repair with multimaterial biomedical devices fabricated from sustainable biopolymers. TISSUE ENGINEERING PART A, Vol. 29(13-14)
- Drop-on-demand micropatterning of novel amphiphilic peptide I3K on regenerated silk fibroin substrates to guide and promote adhesion and proliferation of neuronal cells. TISSUE ENGINEERING PART A, Vol. 29(13-14)
- Tissue repair with multimaterial biomedical devices fabricated from sustainable biopolymers. TISSUE ENGINEERING PART A, Vol. 29(13-14)
- Drop-on-demand micropatterning of novel amphiphilic peptide I3K on regenerated silk fibroin substrates to guide and promote adhesion and proliferation of neuronal cells. TISSUE ENGINEERING PART A, Vol. 29(13-14)
- TISSUE ENGINEERED CARDIAC PATCHES FOR THE TREATMENT OF POST-MI HEART FAILURE USING NATURAL POLYMERS AND HUMAN IPSC-DERIVED CELLS. TISSUE ENGINEERING PART A, Vol. 28 (pp S260-S261)
- A NEXT GENERATION BIO-INSPIRED DEVICE FOR EFFECTIVE PERIPHERAL NERVE REGENERATION. TISSUE ENGINEERING PART A, Vol. 28 (pp S293-S294)
- 3D PRINTING OF POLYHYDROXYALKANOATES FOR CELL CULTURE AND TISSUE REPAIR APPLICATIONS. TISSUE ENGINEERING PART A, Vol. 28 (pp S94-S94)
- AMINE MODIFIED POLYCAPROLACTONE SCAFFOLDS FOR PERIPHERAL NERVE REPAIR. TISSUE ENGINEERING PART A, Vol. 28 (pp S337-S337)
- POLYHYDROXYALKANOATES, NATURAL MATERIALS OF BACTERIAL ORIGIN, IDEAL FOR CARDIAC TISSUE ENGINEERING. TISSUE ENGINEERING PART A, Vol. 28 (pp S36-S37)
- Altering the bubble release of reactive inkjet printed silk micro-rockets. NIP & Digital Fabrication Conference, Vol. 2016 (pp 452-456). Manchester, 12 September 2016 - 12 September 2016.
- Regenerated silk fibroin as an inkjet printable biomaterial. International Conference on Digital Printing Technologies, Vol. 2016 (pp 406-409). Manchester, 12 September 2016 - 12 September 2016.
Other
Preprints
- Grants
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DATE SPONSOR PI/CI/
Named PDRA
TITLE FUNDING March 2023 IAA (UKRI) CoI Production of Polyhydroxyalkanoates for Biomedical applications: Biocompatible, resorbable and sustainable Biomaterials (PoC: Downstream Optimisation and Upstream Scale-up)拢48办 March 2023 EPSRC R-CoI Mussel Inspired Chemistry and Bacteria-synthesized Polymers for a Smart Adhesive Drug Eluting Oral Mucosal Patch (EP/X026108/1)拢550办 March 2023 2x SURF (91直播 Undergraduate Research Fellowship)PI Reactive Inkjet Printed Silk Stirrers for Rapid Medical Diagnosis 2x 拢1,850 Feb 2023 Royce (Summer project grant) PI Feasibility of using Fluorescence assays and Raman Spectroscopy for the design of an online monitoring device to measure the concentration of Polyhydroxyalkanoates during bacterial fermentation. 拢3,200 Jan 2023 Diamond Light Source (Oxford) CoI X-ray tomography for 3D bioprinting (MG33034)Coherence (6 shifts) Diamond Light Source Sep 2022 Diamond Light Source (Oxford) CoI Ptycho-tomography for composite 3D printing for Tissue Engineering (MG31646) Coherence (12 shifts) Diamond Light Source July 2022 BBSRC CoI BBSRC Lean Launch Programme (拢2500 plus 拢1200 for profession consultancy) 拢3,700 April 2019 SURE (91直播 Undergraduate Research Experience) PI Investigating the collective motion of catalytically active micromotors in 3D printed flow cell designs. 拢2,750 Nov 2019 3DBioNET Named PDRA A natural and sustainable biomaterial based 3D model of healthy cardiac tissue. 拢45,740 May 2019 SURF (91直播 Undergraduate Research Fellowship) PI Silk/PEG biogels for reactive inkjet printing and 3D tissue engineering 鈥 for the production of flexible self-motile rockets 拢1,850 May 2019 SURF (91直播 Undergraduate Research Fellowship) PI Silk/PEG biogels for reactive inkjet printing and 3D tissue engineering 鈥 for the production of 3D cell culture scaffolds. 拢1,850 3D BIONET grant: working on the development of Polyhydroxyalkanoates-based 3D Printed tissue repair patches for cardiac tissue applications.
- Teaching activities
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- Module Leader - CPE260 鈥 Experimental Design
- BIE103 - Introduction to Bioengineering
Previous teaching:
- Particle Design and Processing, CPE441
- Structural and Physical Properties of Dental and Bio-materials, MAT6304
- Professional activities and memberships
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Conference Organisation:
- Organiser and Initiator of Bio91直播 2022 Conference
Industrial sponsors:
- Applikon (Gentinge)
- Keyence
- Geneflow
- Cellink (Bico)
- SLS
- Merk
- Co-Organiser of BioMAT 91直播 2023 Microsymposium
Industrial sponsors:
- Applikon (Gentinge)
- Merk
Journal Guest Editor:
鈥溾, Journal of Functional Biomaterials, IF 4.8.
鈥溾, Polymers, IF 5.0.