Ivan B. Dimov scite author profile

Tissue mechanics is important for development; however, the spatio-temporal dynamics of in vivo tissue stiffness is still poorly understood. We here developed tiv-AFM, combining time-lapse in vivo atomic force microscopy with upright fluorescence imaging of embryonic tissue, to show that during development local tissue stiffness changes significantly within tens of minutes. Within this time frame, a stiffness gradient arose in the developing Xenopus brain, and retinal ganglion cell axons turned to follow this gradient. Changes in local tissue stiffness were largely governed by cell proliferation, as perturbation of mitosis diminished both the stiffness gradient and the caudal turn of axons found in control brains. Hence, we identified a close relationship between the dynamics of tissue mechanics and developmental processes, underpinning the importance of time-resolved stiffness measurements.

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Semiconducting Polymers for Neural Applications

Dimov

Moser

Malliaras

et al. 2022

Chem. Rev.

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Electronically interfacing with the nervous system for the purposes of health diagnostics and therapy, sports performance monitoring, or device control has been a subject of intense academic and industrial research for decades. This trend has only increased in recent years, with numerous high-profile research initiatives and commercial endeavors. An important research theme has emerged as a result, which is the incorporation of semiconducting polymers in various devices that communicate with the nervous system—from wearable brain-monitoring caps to penetrating implantable microelectrodes. This has been driven by the potential of this broad class of materials to improve the electrical and mechanical properties of the tissue–device interface, along with possibilities for increased biocompatibility. In this review we first begin with a tutorial on neural interfacing, by reviewing the basics of nervous system function, device physics, and neuroelectrophysiological techniques and their demands, and finally we give a brief perspective on how material improvements can address current deficiencies in this system. The second part is a detailed review of past work on semiconducting polymers, covering electrical properties, structure, synthesis, and processing.

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The C. elegans intestine: organogenesis, digestion, and physiology

Dimov

Maduro

2019

Cell Tissue Res

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Prevention of the foreign body response to implantable medical devices by inflammasome inhibition

Barone

Carnicer‐Lombarte

Tourlomousis

et al. 2022

Proc. Natl. Acad. Sci. U.S.A.

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Significance Implantable electronic medical devices (IEMDs) are used for some clinical applications, representing an exciting prospect for the transformative treatment of intractable conditions such Parkinson’s disease, deafness, and paralysis. The use of IEMDs is limited at the moment because, over time, a foreign body reaction (FBR) develops at the device–neural interface such that ultimately the IEMD fails and needs to be removed. Here, we show that macrophage nucleotide-binding oligomerization domain-like receptor family pyrin domain containing 3 (NLRP3) inflammasome activity drives the FBR in a nerve injury model yet integration of an NLRP3 inhibitor into the device prevents FBR while allowing full healing of damaged neural tissue to occur.

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The electrochemistry of quinizarin revealed through its mediated reduction of oxygen

Batchelor‐McAuley

Dimov

Aldous

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

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After 35 years the hunt for improved anthracycline antibiotics is unabated but has yet to achieve the levels of clinical success desired. Electrochemical techniques provide a large amount of kinetic and thermodynamic information, but the use of such procedures is hindered by issues of sensitivity and selectivity. This work demonstrates how by harnessing the mechanism of catalytic reduction of oxygen by the quinone functionality present within the anthracycline structure it is possible to study the reactive moiety in nanomolar concentration. This methodology allows electrochemical investigation of the intercalation of quinizarin into DNA and, in particular, the quinone oxidation and degradation mechanism. The reversible reduction of the quinizarin, which in the presence of oxygen leads to the formation of reactive oxygen species, is found to occur at −0.535 V (vs. SCE) pH 6.84 and the irreversible oxidation leading to the molecules degradation occurs at 0.386 V (vs. SCE) pH 6.84.electrocatalysis | oxygen reduction | boron-doped diamond

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Ivan B. Dimov

Rapid changes in tissue mechanics regulate cell behaviour in the developing embryonic brain

Semiconducting Polymers for Neural Applications

The C. elegans intestine: organogenesis, digestion, and physiology

Prevention of the foreign body response to implantable medical devices by inflammasome inhibition

The electrochemistry of quinizarin revealed through its mediated reduction of oxygen

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