represent inferior compatibility with biological systems (especially soft brain tissues) due to their high stiffness and long-time stability, which lead to deleterious effects like tissue damage, inflammation, and rejection. [4] Flexible and stretchable polymeric fibers with designed microstructures are explored for neurological studies, enabling integrated electrical sensing, optical stimulation, and controlled microfluidic delivery. [5] In medical practice, biodegradable organic and inorganic materials including metals, semiconductors, and polymers have been exploited to form biological structures (drugs, stents, scaffolds, etc.) [6] and functional devices (electrical, optical, mechanical, and thermal sensors). [7] In comparison to devices and systems made of inert materials, these biodegradable implants that can physically disappear in biological tissues to eliminate the risk associated with further retraction or removal, providing enormous potential to biomedical applications and particularly clinical uses. Recently, waveguides and photonic structures based on biodegradable materials like ceramics (e.g., calcium phosphates), [8] synthetic polymers, [9] hydrogels, [10] and even bioderived materials (e.g., silks) [11] are investigated in both in vitro and in vivo studies. So far, these biodegradable photonic materials and structures have not been utilized as implantable fibers to study deep-brain neural activities. Here, we present poly(l-lactic acid) (PLLA)-based optical fibers as a biodegradable Advanced optical fibers and photonic structures play important roles in neuroscience research, along with recent progresses of genetically encoded optical actuators and indicators. Most techniques for optical neural implants rely on fused silica or long-lasting polymeric fiber structures. In this paper, implantable and biodegradable optical fibers based on poly(l-lactic acid) (PLLA) are presented. PLLA fibers with dimensions similar to standard silica fibers are constructed using a simple thermal drawing process at around 220 °C. The formed PLLA fibers exhibit high mechanical flexibility and optical transparency, and their structural evolution and optical property changes are systematically studied during in vitro degradation. In addition, their biocompatibility with brain tissues is evaluated in living mice, and full in vivo degradation is demonstrated. Finally, PLLA fibers are implemented as a tool for intracranial light delivery and detection, realizing deep brain fluorescence sensing and optogenetic interrogation in vivo. The presented materials and device platform offer paths to fully biocompatible and bioresorbable photonic systems for biomedical uses.
Biodegradable Fibers
