Exploring Biomineralization Processes Using In Situ Liquid Transmission Electron Microscopy: A Review
Abstract: Liquid transmission electron microscopy (TEM) is a newly established technique broadly used to study reactions in situ. Since its emergence, complex and multifaceted biomineralization processes have been revealed with real‐time resolution, where classical and non‐classical mineralization pathways have been dynamically observed primarily for Ca and Fe‐based mineral systems in situ. For years, classical crystallization pathways have dominated theories on biomineralization progression despite observations of non‐traditional routes involving precursor phases using traditional‐ and cryo‐TEM. The new dynamic lens provided by liquid TEM is a key correlate to techniques limited to time‐stamped, static observations – helping shift paradigms in biomineralization toward non‐classical theories with dynamic mechanistic visualization. Liquid TEM provides new insights into fundamental biomineralization processes and essential physiological and pathological processes for a wide range of organisms. This review critically reviews a summary of recent in situ liquid TEM research related to the biomineralization field. Key liquid TEM preparation and imaging parameters are provided as a foundation for researchers while technical challenges are discussed. In future, the expansion of liquid TEM research in the biomineralization field will lead to transformative discoveries, providing complementary dynamic insights into biological systems.
- Standort
-
Deutsche Nationalbibliothek Frankfurt am Main
- Umfang
-
Online-Ressource
- Sprache
-
Englisch
- Erschienen in
-
Exploring Biomineralization Processes Using In Situ Liquid Transmission Electron Microscopy: A Review ; day:10 ; month:11 ; year:2024 ; extent:24
Small ; (10.11.2024) (gesamt 24)
- Urheber
-
DiCecco, Liza‐Anastasia
Tang, Tengteng
Sone, Eli D.
Grandfield, Kathryn
- DOI
-
10.1002/smll.202407539
- URN
-
urn:nbn:de:101:1-2411111308096.078690333206
- Rechteinformation
-
Open Access; Der Zugriff auf das Objekt ist unbeschränkt möglich.
- Letzte Aktualisierung
-
15.08.2025, 07:32 MESZ
Datenpartner
Deutsche Nationalbibliothek. Bei Fragen zum Objekt wenden Sie sich bitte an den Datenpartner.
Beteiligte
- DiCecco, Liza‐Anastasia
- Tang, Tengteng
- Sone, Eli D.
- Grandfield, Kathryn
Ähnliche Objekte (12)
Biomineralization of calcium phosphate revealed by in situ liquid-phase electron microscopy
Quantification of Electron Beam-Induced Effects in Liquid-Phase Transmission Electron Microscopy
Mapping and Controlling Liquid Layer Thickness in Liquid‐Phase (Scanning) Transmission Electron Microscopy
Assessment of oxide nanoparticle stability in liquid phase transmission electron microscopy
Pitfalls in Electrochemical Liquid Cell Transmission Electron Microscopy for Dendrite Observation
Energy filtering transmission electron microscopy
Defect Investigations by Transmission Electron Microscopy
Transmission Electron Microscopy on Memristive Devices
Influence of the beam and window material on liquid phase transmission electron microscopy
Erratum to: Assessment of oxide nanoparticle stability in liquid phase transmission electron microscopy
Material Contrast by Scanning Electron Microscopy and Low-Energy Scanning Transmission Electron Microscopy
Growth of dendritic nanostructures by liquid-cell transmission electron microscopy: a reflection of the electron-irradiation history
Biomineralization of calcium phosphate revealed by in situ liquid-phase electron microscopy
Quantification of Electron Beam-Induced Effects in Liquid-Phase Transmission Electron Microscopy
Mapping and Controlling Liquid Layer Thickness in Liquid‐Phase (Scanning) Transmission Electron Microscopy
Assessment of oxide nanoparticle stability in liquid phase transmission electron microscopy
Pitfalls in Electrochemical Liquid Cell Transmission Electron Microscopy for Dendrite Observation
Energy filtering transmission electron microscopy
Defect Investigations by Transmission Electron Microscopy
Transmission Electron Microscopy on Memristive Devices
Influence of the beam and window material on liquid phase transmission electron microscopy
Erratum to: Assessment of oxide nanoparticle stability in liquid phase transmission electron microscopy
Material Contrast by Scanning Electron Microscopy and Low-Energy Scanning Transmission Electron Microscopy
Growth of dendritic nanostructures by liquid-cell transmission electron microscopy: a reflection of the electron-irradiation history
Biomineralization of calcium phosphate revealed by in situ liquid-phase electron microscopy
Quantification of Electron Beam-Induced Effects in Liquid-Phase Transmission Electron Microscopy
Mapping and Controlling Liquid Layer Thickness in Liquid‐Phase (Scanning) Transmission Electron Microscopy
Assessment of oxide nanoparticle stability in liquid phase transmission electron microscopy
Pitfalls in Electrochemical Liquid Cell Transmission Electron Microscopy for Dendrite Observation
Energy filtering transmission electron microscopy
Defect Investigations by Transmission Electron Microscopy
Transmission Electron Microscopy on Memristive Devices
Influence of the beam and window material on liquid phase transmission electron microscopy
Erratum to: Assessment of oxide nanoparticle stability in liquid phase transmission electron microscopy
Material Contrast by Scanning Electron Microscopy and Low-Energy Scanning Transmission Electron Microscopy