Incorporation of Terbium into a Microalga Leads to Magnetotactic Swimmers

Santomauro, Giulia; Singh, Anurag; Park, Byung‐wook; Mohammadrahimi, Mohammadreza; Erkoc, Pelin; Goering, E.; Schütz, Gisela; Sitti, Metin

doi:10.1002/adbi.201800039

Cited by 43 publications

(35 citation statements)

References 58 publications

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“…Of particular interest are magnetotactic bacteria, which can readily be steered by applying magnetic fields [7,8]. Organisms that are not naturally magnetotactic can also be controlled with magnetic fields after incorporation of magnetic particles; this has recently been demonstrated with the alga Chlamydomonas reinhardtii [9]. Commonly studied magnetotactic bacteria include the strains MO-1 and MC-1 ( Magnetococcus marinus ), which are similar in morphology and differ from the species most widely studied in other contexts, such as Escherichia coli , Bacillus subtilis , or Vibrio alginolyticus .…”

Section: Introductionmentioning

confidence: 99%

Microswimmer Propulsion by Two Steadily Rotating Helical Flagella

Shum

2019

Micromachines

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Many theoretical studies of bacterial locomotion adopt a simple model for the organism consisting of a spheroidal cell body and a single corkscrew-shaped flagellum that rotates to propel the body forward. Motivated by experimental observations of a group of magnetotactic bacterial strains, we extended the model by considering two flagella attached to the cell body and rotating about their respective axes. Using numerical simulations, we analyzed the motion of such a microswimmer in bulk fluid and close to a solid surface. We show that positioning the two flagella far apart on the cell body reduces the rate of rotation of the body and increases the swimming speed. Near surfaces, we found that swimmers with two flagella can swim in relatively straight trajectories or circular orbits in either direction. It is also possible for the swimmer to escape from surfaces, unlike a model swimmer of similar shape but with only a single flagellum. Thus, we conclude that there are important implications of swimming with two flagella or flagellar bundles rather than one. These considerations are relevant not only for understanding differences in bacterial morphology but also for designing microrobotic swimmers.

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Section: Introductionmentioning

confidence: 99%

Microswimmer Propulsion by Two Steadily Rotating Helical Flagella

Shum

2019

Micromachines

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“…Different lanthanides accumulate in different parts of the cells 32. We also showed that the microalgae species Chlamydomonas reinhardtii , which does not produce coccoliths, takes up Tb 3+ and accumulates them as nanoparticles inside the cells 33. The accumulation of lanthanides in coccoliths were not investigated so far.…”

Section: Introductionmentioning

confidence: 94%

In Vivo Shaping of Inorganic Functional Devices using Microalgae

2020

Self Cite

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The usage of biomineralization processes performed by living microalgae to create 3D nanostructured materials are advantageous compared to conventional synthesis routes. Exploitation of in vivo shaping using living cells leads to inorganic intricate biominerals, produced with low environmental impact. Since biomineralization processes are genetically controlled, the formation of nanostructured materials is highly reproducible. The shells of microalgae, like coccoliths, are particularly of great interest. This study shows the generation of mesoporous highly structured functional materials with induced optoelectronical properties using in vivo processes of the microalga species Emiliania huxleyi. It demonstrates the metabolically driven incorporation of the lanthanide terbium into the coccoliths of E. huxleyi as a route for the synthesis of finely patterned photoluminescent particles by feeding the microalgae with this luminescent element. The resulting green luminescent particles have hierarchical ordered pores on the nano‐ and microscale and may act as powerful tools for many applications; they may serve as imaging probes for biomedical applications, or in microoptics. The luminescent coccoliths combine a unique hierarchical structure with a characteristic luminescence pattern, which make them superior to conventional produced Tb doted material. With this study, the possibility of the further exploitation of coccoliths as advanced functional materials for nanotechnological applications is given.

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“…An approach to provide magnetic properties to the microalga species C. reinhardtii is to culture them in a media containing terbium ions (Tb 3 + ). [ 237 ] These ions are known to possess magnetic properties and to present photoluminescence and could therefore potentially be used as a biomarker. The grown microalgae presented superparamagnetic properties and their motion could be controlled by magnetic fields and tracked by their photoluminescence.…”

Section: Magnetic Biohybrid Cellular Micro‐biorobotsmentioning

confidence: 99%

Magnetic Actuation Methods in Bio/Soft Robotics

Ebrahimi

Cappelleri

et al. 2020

Adv Funct Materials

175

104

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In recent years, magnetism has gained an enormous amount of interest among researchers for actuating different sizes and types of bio/soft robots, which can be via an electromagnetic‐coil system, or a system of moving permanent magnets. Different actuation strategies are used in robots with magnetic actuation having a number of advantages in possible realization of microscale robots such as bioinspired microrobots, tetherless microrobots, cellular microrobots, or even normal size soft robots such as electromagnetic soft robots and medical robots. This review provides a summary of recent research in magnetically actuated bio/soft robots, discussing fabrication processes and actuation methods together with relevant applications in biomedical area and discusses future prospects of this way of actuation for possible improvements in performance of different types of bio/soft robots.

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Incorporation of Terbium into a Microalga Leads to Magnetotactic Swimmers

Cited by 43 publications

References 58 publications

Microswimmer Propulsion by Two Steadily Rotating Helical Flagella

Microswimmer Propulsion by Two Steadily Rotating Helical Flagella

In Vivo Shaping of Inorganic Functional Devices using Microalgae

Magnetic Actuation Methods in Bio/Soft Robotics

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