A biohybrid synapse with neurotransmitter-mediated plasticity

Keene, Scott T.; Lubrano, Claudia; Kazemzadeh, Setareh; Melianas, Armantas; Tuchman, Yaakov; Polino, Giuseppina; Scognamiglio, Paola; Cinà, Lucio; Salleo, Alberto; Burgt, Yoeri van de; Santoro, Francesca

doi:10.1038/s41563-020-0703-y

Cited by 254 publications

(281 citation statements)

References 36 publications

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“…31,50 Recently, it was demonstrated that biological cells can directly modulate the long-term state of organic neuromorphic devices depending on the amount of neurotransmitter released. 51 This work shows how integrated adaptive connections can work for hybrid biological/neuromorphic systems.…”

Section: Integration With Biologymentioning

confidence: 97%

Organic neuromorphic devices: Past, present, and future challenges

et al. 2020

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Section: Integration With Biologymentioning

confidence: 97%

Organic neuromorphic devices: Past, present, and future challenges

et al. 2020

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“…[ 8,16–19 ] Recent years have seen growing research activities in the field of organic memristors, [ 20,21 ] and their performance has been demonstrated to be comparable to biological synapses, [ 12,22 ] hence highly promising for processing biological signals. [ 23,24 ] Importantly, the operational stability of organic memristors can rival that of inorganic memristors. [ 25–27 ]…”

Section: Figurementioning

confidence: 99%

A Monochloro Copper Phthalocyanine Memristor with High‐Temperature Resilience for Electronic Synapse Applications

Zhou

Chen

et al. 2020

Advanced Materials

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Memristors are considered to be one of the most promising device concepts for neuromorphic computing, in particular thanks to their highly tunable resistive states. To realize neuromorphic computing architectures, the assembly of large memristive crossbar arrays is necessary, but is often accompanied by severe heat dispassion. Organic materials can be tailored with on‐demand electronic properties in the context of neuromorphic applications. However, such materials are more susceptible to heat, and detrimental effects such as thermally induced degradation directly lead to failure of device operation. Here, an organic memristive synapse formed of monochloro copper phthalocyanine, which remains operational and capable of memristive switching at temperatures as high as 300 °C in ambient air without any encapsulation, is demonstrated. The change in the electrical conductance is found to be a result of ion movement, closely resembling what takes place in biological neurons. Furthermore, the high viability of this approach is showcased by demonstrating flexible memristors with stable switching behaviors after repeated mechanical bending as well as organic synapses capable of emulating a trainable and reconfigurable memristor array for image information processing. The results set a precedent for thermally resilient organic synapses to impact organic neuromorphic devices in progressing their practicality.

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“…Recently, a path toward scalable organic-based networks has been shown for parallel programming/training, by combining electrochemical organic neuromorphic devices with an ionic diode (memristive switching device) as the access device. 67 Of particular interest for future applications, is the use of such ANNs in a more generic neuromorphic system, a hybrid agent, [78][79][80][81] for local signal processing in bioelectronics. 18 Indeed, concepts of local processing and feature extraction can minimize data transfer from the acquisition site to peripheral electronics, thereby allowing for fully autonomous applications in bioelectronics.…”

Section: Organic Devices For Brain-inspired Computing Artificial Implmentioning

confidence: 99%