Probing Single-Cell Macrophage Polarization and Heterogeneity Using Thermo-Reversible Hydrogels in Droplet-Based Microfluidics

Tiemeijer, B. M.; Sweep, M. W. D.; Sleeboom, Jelle J. F.; Steps, K. J.; Sprang, Johnick F. van; Almeida, Paula de; Hammink, Roel; Kouwer, Paul H. J.; Smits, Anthal I.P.M.; Tel, Jurjen

doi:10.3389/fbioe.2021.715408

Cited by 21 publications

(18 citation statements)

References 51 publications

(81 reference statements)

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“…Encapsulation of cells in aqueous droplets will result in cells being in forced suspension. This is fine for non-adherent cells but might affect the viability and phenotype of adherent cells that require mechanical stimuli and attachment molecules (Gilmore, 2005;Taddei et al, 2012;Tiemeijer et al, 2021). As hydrogels often mimic the stiffness of extracellular matrix and can be functionalized to facilitate adherence, production of microgels can open the technology to a broader range of cell applications.…”

Section: Discussionmentioning

confidence: 99%

“…The addition of hydrogel in droplets to produce microgels proves a double-edged sword, providing solutions to both problems. Cellular adherence and mechanical cues can be provided via biocompatible hydrogels providing a semi-solid extracellular matrix-like environment (Dumbleton et al, 2016;Hasturk and Kaplan, 2019;Tiemeijer et al, 2021). On the other hand, the hydrogel can maintain spatial control over cells after de-emulsification while allowing for diffusion and downstream processing using analytes or other reagents (Leonaviciene et al, 2020;di Girolamo et al, 2020;Yanakieva et al, 2020;Chokkalingam et al, 2013).…”

Section: Microfluidicsmentioning

confidence: 99%

“…Therefore, the type of crosslinking dictates droplet formation and adjustments that need to be made to device design. Commonly used types are ionic cross-linking (Choi et al, 2007;Workman et al, 2007;Utech et al, 2015;Ahmed and Stokke, 2021), photo-cross-linking (Zhao et al, 2016;Mohamed et al, 2019;Nan et al, 2019), and thermoresponsive cross-linking (Dolega et al, 2015;Yanakieva et al, 2020;Tiemeijer et al, 2021;Zhang et al, 2021). By design, the latter two do not require on-chip mixing of different aqueous phases and can still be used in conventional device designs.…”

Section: Microfluidicsmentioning

confidence: 99%

“…Many immune responses are heavily dependent on cells being adjacent for paracrine signaling or even connecting for juxtacrine signaling. High-throughput droplet encapsulation was readily proven an ideal method to screen immune cell heterogeneity in response to paracrine ques, as modeled by co-encapsulation of various stimuli (Tiemeijer et al, 2021;Konry et al, 2011;van Eyndhoven et al, 2021;Konry et al, 2013). Co-encapsulation allows similar setups for investigating contact-dependent juxtacrine interactions referred to as immune synapses.…”

Section: Pairing For Single-cell Immune Assaysmentioning

confidence: 99%

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Hydrogels for Single-Cell Microgel Production: Recent Advances and Applications

Tiemeijer

Tel

2022

Front. Bioeng. Biotechnol.

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Single-cell techniques have become more and more incorporated in cell biological research over the past decades. Various approaches have been proposed to isolate, culture, sort, and analyze individual cells to understand cellular heterogeneity, which is at the foundation of every systematic cellular response in the human body. Microfluidics is undoubtedly the most suitable method of manipulating cells, due to its small scale, high degree of control, and gentle nature toward vulnerable cells. More specifically, the technique of microfluidic droplet production has proven to provide reproducible single-cell encapsulation with high throughput. Various in-droplet applications have been explored, ranging from immunoassays, cytotoxicity assays, and single-cell sequencing. All rely on the theoretically unlimited throughput that can be achieved and the monodispersity of each individual droplet. To make these platforms more suitable for adherent cells or to maintain spatial control after de-emulsification, hydrogels can be included during droplet production to obtain “microgels.” Over the past years, a multitude of research has focused on the possibilities these can provide. Also, as the technique matures, it is becoming clear that it will result in advantages over conventional droplet approaches. In this review, we provide a comprehensive overview on how various types of hydrogels can be incorporated into different droplet-based approaches and provide novel and more robust analytic and screening applications. We will further focus on a wide range of recently published applications for microgels and how these can be applied in cell biological research at the single- to multicell scale.

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Section: Discussionmentioning

confidence: 99%

Section: Microfluidicsmentioning

confidence: 99%

Section: Microfluidicsmentioning

confidence: 99%

Section: Pairing For Single-cell Immune Assaysmentioning

confidence: 99%

See 2 more Smart Citations

Hydrogels for Single-Cell Microgel Production: Recent Advances and Applications

Tiemeijer

Tel

2022

Front. Bioeng. Biotechnol.

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“…Tiemeijer et al. [ 64 ] used PDMS devices with a flow-focusing geometry to study the biological function of human monocyte-derived macrophages at single-cell resolution with high throughput. HFE oil was inserted into the microchannels via the outermost inlet, while cells and the thermoreversible polyisocyanide (PIC) with cytokines (LPS and IFN-γ for a proinflammatory M1 phenotype or IL-4 and IL-13 for a prohealing M2 phenotype) were inserted from the inner two inlets.…”

Section: Encapsulation Technologies For Angiogenic Therapymentioning

confidence: 99%

Trends in hydrogel-based encapsulation technologies for advanced cell therapies applied to limb ischemia

Costa

Willerth

Torre

et al. 2022

Materials Today Bio

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Stimuli‐Mediated Macrophage Switching, Unraveling the Dynamics at the Nanoplatforms–Macrophage Interface

Ganguly,

Luthfikasari,

Randhawa

et al. 2024

Adv Healthcare Materials

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Macrophages play an essential role in immunotherapy and tissue regeneration owing to their remarkable plasticity and diverse functions. Recent bioengineering developments have focused on using external physical stimuli such as electric and magnetic fields, temperature, and compressive stress, among others, on micro/nanostructures to induce macrophage polarization, thereby increasing their therapeutic potential. However, it is difficult to find a concise review of the interaction between physical stimuli, advanced micro/nanostructures, and macrophage polarization. This review examines the present research on physical stimuli‐induced macrophage polarization on micro/nanoplatforms, emphasizing the synergistic role of fabricated structure and stimulation for advanced immunotherapy and tissue regeneration. We provide a concise overview of the research advancements investigating the impact of physical stimuli‐including electric fields, magnetic fields, compressive forces, fluid shear stress, photothermal stimuli, and multiple stimulations on the polarization of macrophages within complex engineered structures. The prospective implications of these strategies in regenerative medicine and immunotherapeutic approaches have been highlighted. This review will aid in creating stimuli‐responsive platforms for immunomodulation and tissue regeneration.This article is protected by copyright. All rights reserved

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Probing Single-Cell Macrophage Polarization and Heterogeneity Using Thermo-Reversible Hydrogels in Droplet-Based Microfluidics

Cited by 21 publications

References 51 publications

Hydrogels for Single-Cell Microgel Production: Recent Advances and Applications

Hydrogels for Single-Cell Microgel Production: Recent Advances and Applications

Trends in hydrogel-based encapsulation technologies for advanced cell therapies applied to limb ischemia

Stimuli‐Mediated Macrophage Switching, Unraveling the Dynamics at the Nanoplatforms–Macrophage Interface

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