Miniaturized neural system for chronic, local intracerebral drug delivery

Dağdeviren, Canan; Ramadi, Khalil B.; Joe, Pauline; Spencer, Kevin C.; Schwerdt, Helen N.; Shimazu, Hideki; Delcasso, Sebastien; Amemori, Ken‐ichi; Nunez-Lopez, Carlos; Graybiel, Ann M.; Cima, Michael J.; Langer, Robert

doi:10.1126/scitranslmed.aan2742

Cited by 76 publications

(89 citation statements)

References 52 publications

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“…Our group has previously demonstrated reduced glial scarring in response to smaller implant diameters, down to 150 µm . Implants that incorporate highly flexible, low‐diameter materials to reduce associated inflammation are thus termed “microinvasive.” Microinvasive implants are capable of targeting deep‐brain structures with increased spatial resolution and minimal scarring . These studies reinforce the necessity for further reducing implant diameter to improve chronic viability and spatial resolution.…”

Section: Introductionmentioning

confidence: 62%

“…A custom 3D‐printed cap was fabricated as a coimplant to prevent device migration during chronic implantation (Figure S1a, Supporting Information). S‐MINIs were implanted into the substantia nigra (anteroposterior (AP): −5.0 mm, mediolateral (ML): −2.2 mm, dorsoventral (DV): −8.2 mm) of rats using previously established implantation procedures (Figure b; Figure S1b, Supporting Information) . Histological analysis of glial scarring was performed after 8 weeks of implantation using previously developed methods (Figure c) .…”

Section: Resultsmentioning

confidence: 99%

“…Guide tubes and protective sheaths have often been necessary to improve implant stability and prevent buckling during insertion when designs require long, thin implants . The use of thick exterior coatings removes the benefit of size reduction in glial scarring granted by smaller implants.…”

Section: Discussionmentioning

confidence: 99%

“…S‐MINI Implantation : All in vivo studies were completed following previously reported methods . Briefly, F344 (SAS Fischer) female rats were purchased form Charles River Laboratories and sustained under 12 h light/dark cycles.…”

Section: Methodsmentioning

confidence: 99%

“…Reliably guiding small‐diameter implants with high aspect ratios to deep structures is challenging and often requires external control to predictably guide the long, thin implants to a final location . Many devices employ shuttles to facilitate insertion, such as hydrogel coatings and guide tubes . The use of such shuttles increases device diameter, potentially mitigating the benefits to gliosis reduction.…”

Section: Introductionmentioning

confidence: 99%

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Steerable Microinvasive Probes for Localized Drug Delivery to Deep Tissue

Cotler

Rousseau

Ramadi

et al. 2019

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Enhanced understanding of neuropathologies has created a need for more advanced tools. Current neural implants result in extensive glial scarring and are not able to highly localize drug delivery due to their size. Smaller implants reduce surgical trauma and improve spatial resolution, but such a reduction requires improvements in device design to enable accurate and chronic implantation in subcortical structures. Flexible needle steering techniques offer improved control over implant placement, but often require complex closed‐loop control for accurate implantation. This study reports the development of steerable microinvasive neural implants (S‐MINIs) constructed from borosilicate capillaries (OD = 60 µm, ID = 20 µm) that do not require closed‐loop guidance or guide tubes. S‐MINIs reduce glial scarring 3.5‐fold compared to prior implants. Bevel steered needles are utilized for open‐loop targeting of deep‐brain structures. This study demonstrates a sinusoidal relationship between implant bevel angle and the trajectory radius of curvature both in vitro and ex vivo. This relationship allows for bevel‐tipped capillaries to be steered to a target with an average error of 0.23 mm ± 0.19 without closed‐loop control. Polished microcapillaries present a new microinvasive tool for chronic, predictable targeting of pathophysiological structures without the need for closed‐loop feedback and complex imaging.

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Section: Introductionmentioning

confidence: 62%

Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Steerable Microinvasive Probes for Localized Drug Delivery to Deep Tissue

Cotler

Rousseau

Ramadi

et al. 2019

Small

Self Cite

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Multifunctional Fibers to Shape Future Biomedical Devices

Zhang

Ding

et al. 2019

Adv Funct Materials

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Fiber-based configurations are highly desirable for wearable and implantable biomedical devices due to their unique properties, such as ultra-flexibility, weavability, minimal invasiveness, and tissue adaptability. Recent developments have focused on the fabrication of fibrous devices with multiple biomedical functions, such as noninvasively or minimally invasively monitoring of physiological signals, delivering drugs, transplanting cells, and recording and stimulating nerves. In this Review, the recent progress of these multifunctional fiber-based devices in terms of their composite materials, fabrication techniques, structural designs, device-tissue interfaces, and biomedical applications is carefully described. The remaining challenges and future directions in this emerging and exciting research field are also highlighted.

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Spatiotemporally Controllable Chemical Delivery Utilizing Electroosmotic Flow Generated in Combination of Anionic and Cationic Hydrogels

Terutsuki,

Miyazawa,

Takagi

et al. 2023

Adv Funct Materials

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Spatiotemporally controlled chemical delivery is crucial for various biomedical engineering applications. Here, a novel concept of electrically controllable delivery utilizing electroosmotic flow (EOF) generated in a combination of anionic and cationic hydrogels (A‐ and C‐hydrogels) is reported. The unique advantages of the A/C‐hydrogel combination are demonstrated utilizing a flexible sheet‐shaped and a thin tubular devices. Since the directions of EOF in the A‐ and C‐hydrogels are opposite to each other, the ionic current for EOF generation flows inside the delivery devices, enabling chemical delivery without accompanying external ionic current that could stimulate target cells and tissues. A thin tubular device, which can be inserted into narrow in vivo structures and be integrated with other flexible devices, exhibits high robustness and repeatability thanks to the flexibility and water retentivity of hydrogels. The EOF devices with A/C‐hydrogels combination show high controllability superior to the pumping with a conventional syringe; the volumetric flow rate is able to be controlled proportionally to the current applied, for example, ≈0.4 µL (mA min)−1 for the tubular device. The developed EOF‐based devices are versatile for delivery of most chemicals regardless of their charge and size, and have great potential for both biomedical researches and therapeutics.

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Miniaturized neural system for chronic, local intracerebral drug delivery

Cited by 76 publications

References 52 publications

Steerable Microinvasive Probes for Localized Drug Delivery to Deep Tissue

Steerable Microinvasive Probes for Localized Drug Delivery to Deep Tissue

Multifunctional Fibers to Shape Future Biomedical Devices

Spatiotemporally Controllable Chemical Delivery Utilizing Electroosmotic Flow Generated in Combination of Anionic and Cationic Hydrogels

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