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Fluorescent probes are an indispensable tool in the realm of bioimaging technologies, providing valuable insights into the assessment of biomaterial integrity and structural properties. However, incorporating fluorophores into scaffolds made from melt electrowriting (MEW) poses a challenge due to the sustained, elevated temperatures that this processing technique requires. In this context, [n]cycloparaphenylenes ([n]CPPs) serve as excellent fluorophores for MEW processing with the additional benefit of customizable emissions profiles with the same excitation wavelength. Three fluorescent blends are used with distinct [n]CPPs with emission wavelengths of either 466, 494, or 533 nm, identifying 0.01 wt% as the preferred concentration. It is discovered that [n]CPPs disperse well within poly(epsilon-caprolactone) (PCL) and maintain their fluorescence even after a week of continuous heating at 80 degrees C. The [n]CPP-PCL blends show no cytotoxicity and support counterstaining with commonly used DAPI (Ex/Em: 359 nm/457 nm), rhodamine- (Ex/Em: 542/565 nm), and fluorescein-tagged (Ex/Em: 490/515 nm) phalloidin stains. Using different color [n]CPP-PCL blends, different MEW fibers are sequentially deposited into a semi-woven scaffold and onto a solution electrospun membrane composed of [8]CPP-PCL as a contrasting substrate for the [10]CPP-PCL MEW fibers. In general, [n]CPPs are potent fluorophores for MEW, providing new imaging options for this technology.|New fluorescent probes are used for a microfiber 3D printing technology, called melt electrowriting. Their emission strength, process stability, cytotoxicity, and general ease of use makes these probes an excellent tool for biofabrication with living systems. Since scaffold-cell interactions heavily use fluorescent imaging technique, the study contributes to the understanding of long-term tissue construct monitoring. image
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Michael Stefan Daniel Liebling, Christian Jaques
Edoardo Charbon, Claudio Bruschini, Arin Can Ülkü