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Abstract

Stimuli-responsive hydrogels are promising candidates for use in the targeted delivery of drugs using microrobotics. These devices enable the delivery and sustained release of quantities of drugs several times greater than their dry weight and are responsive to external stimuli. However, existing systems have two major drawbacks: (1) severe drug leakage before reaching the targeted areas within the body and (2) impeded locomotion through liquids due to the inherent hydrophilicity of hydrogels. This article outlines an approach to the assembly of hydrogel-based microcapsules in which one device is assembled within another to prevent drug leakage during transport. Inspired by the famous Russian stacking dolls (Matryoshka), the proposed scheme not only improves drug-loading efficiency but also facilitates the movement of hydrogel-based microcapsules driven by an external magnetic field. At room temperature, drug leakage from the hydrogel matrix is 90%. However, at body temperature the device folds up and assembles to encapsulate the drug, thereby reducing leakage to a mere 6%. The Matryoshka-inspired micro-origami capsule (MIMC) can disassemble autonomously when it arrives at a targeted site, where the temperature is slightly above body temperature. Up to 30% of the encapsulated drug was shown to diffuse from the hydrogel matrix within 1 h when it unfolds and disassembles. The MIMC is also shown to enhance the movement of magnetically driven microcapsules while navigating through media with a low Reynolds number. The translational velocity of the proposed MIMC (four hydrogel-based microcapsules) driven by magnetic gradients is more than three times greater than that of a conventional (single) hydrogel-based microcapsule.

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References

Nelson

, Kaliakatsos

, Abbott

. Microrobots for minimally invasive medicine. Annu Rev Biomed Eng, 2010; 12:55–85.

, Esteban-Fernández de Ávila

, Gao

, et al. Micro/nanorobots for biomedicine: delivery, surgery, sensing, and detoxification. Sci Robot, 2017; 2:eaam6431.

Banerjee

, Ren

. Optimizing double-network hydrogel for biomedical soft robots. Soft Robot, 2017; 4:191–201.

Miyashita

, Guitron

, Yoshida

, et al. Ingestible, controllable, and degradable origami robot for patching stomach wounds. In: IEEE International Conference on Robotics and Automation (ICRA), Stockholm, Sweden: IEEE, 2016 May 16–21, pp. 909–916.

Wood

, Walsh

. Smaller, softer, safer, smarter robots. Sci Transl Med, 2013; 5:210ed19.

, Mooney

. Designing hydrogels for controlled drug delivery. Nat Rev Mater, 2016; 1:pii: 16071.

Hoare

, Kohane

. Hydrogels in drug delivery: progress and challenges. Polymer, 2008; 49:1993–2007.

Zhang

, Khademhosseini

. Advances in engineering hydrogels. Science, 2017; 356:pii: eaaf3627.

Lin

, Yuk

, Zhang

, et al. Stretchable hydrogel electronics and devices. Adv Mater, 2016; 28:4497–4505.

10.

Hibbins

, Kumar

, Choonara

, et al. Design of a versatile pH-responsive hydrogel for potential oral delivery of gastric-sensitive bioactives. Polymers, 2017; 9:474.

11.

Wirthl

, Pichler

, Drack

, et al. Engineering instant tough bonding of hydrogels for soft machines and electronics. Sci Adv, 2017; 3:1–9.

12.

Baek

, Jeong

, Shkumatov

, et al. In situ self-folding assembly of a multi-walled hydrogel tube for uniaxial sustained molecular release. Adv Mater, 2013; 25:5568–5573.

13.

Fusco

, Huang

, Peyer

et al. Shape-switching microrobots for medical applications: the influence of shape in drug delivery and locomotion. ACS Appl Mater Interfaces, 2015; 7:6803–6811.

14.

Fusco

, Sakar

, Kennedy

, et al. An integrated microrobotic platform for on-demand, targeted therapeutic interventions. Adv Mater, 2014; 26:533–538.

15.

Jeon

, Hauser

, Hayward

. Shape-morphing materials from stimuli-responsive hydrogel hybrids. Acc Chem Res, 2017; 50:161–169.

16.

Pedron

, Lierop

, Horstman

, et al. Stimuli responsive delivery vehicles for cardiac microtissue transplantation. Adv Funct Mater, 2011; 21:1624–1630.

17.

Stuart

MAC

, Huck

WTS

, Genzer

, et al. Emerging applications of stimuli-responsive polymer materials. Nat Mater, 2010; 9:101–113.

18.

Gultepe

, Randhawa

, Kadam

, et al. Biopsy with thermally-responsive untethered microtools. Adv Mater, 2013; 25:514–519.

19.

Kuo

, Tung

, Yang

. A hydrogel-based intravascular microgripper manipulated using magnetic fields. Sens Actuators A Phys, 2013; 211:1683–1686.

20.

Jamal

, Kadam

, Xiao

, et al. Bio-origami hydrogel scaffolds composed of photocrosslinked PEG bilayers. Adv Heal Mater, 2013; 2:1142–1150.

21.

Manikas

, Aliberti

, Causa

, et al. Thermoresponsive PNIPAAm hydrogel scaffolds with encapsulated AuNPs show high analyte-trapping ability and tailored plasmonic properties for high sensing efficiency. J Mater Chem B, 2015; 3:53.

22.

, Yan

, Jang

et al. Assembly of micro/nanomaterials into complex, three-dimensional architectures by compressive buckling. Science, 2015; 347:154–159.

23.

Ionov

. Hydrogel-based actuators: possibilities and limitations. Mater Today, 2014; 17:494–503.

24.

Huang

, Petruska

, Sakar

, et al. Self-folding hydrogel bilayer for enhanced drug loading, encapsulation, and transport. In: Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC), Orlando, FL: IEEE, 2016 August 16–20, pp. 2103–2106.

25.

Huang

, Sakar

, Riederer

, et al. Magnetic microrobots with addressable shape control. In: IEEE International Conference on Robotics and Automation (ICRA), Stockholm, Sweden: IEEE, 2016 May 16–21, pp. 2103–2106.

26.

Dinarvand

, D'Emanuele

. The use of thermoresponsive hydrogels for on-off release of molecules. J Control Release, 1995; 36:221–227.

27.

Malachowski

, Breger

, Kwag

et al. Stimuli-responsive theragrippers for chemomechanical controlled release. Angew Chem Int Ed, 2014; 53:8045–8049.

28.

Purcell

. Life at low Reynolds number. Am J Phys, 1977; 45:3.

29.

Happel

, Brenner

. Low Reynolds Number Hydrodynamics: With Special Applications to Particulate Media. Dordrecht, Netherlands: Springer, 1983.

30.

Peters

, Hoop

, Pané

, et al. Degradable magnetic composites for minimally invasive interventions: device fabrication, targeted drug delivery, and cytotoxicity tests. Adv Mater, 2016; 28:533–538.

31.

Breger

, Yoon

, Xiao

, et al. Self-folding thermo-magnetically responsive soft microgrippers. ACS Appl Mater Interfaces, 2015; 7:3398–3405.

32.

Huang

, Sakar

, Petruska

et al. Soft micromachines with programmable motility and morphology. Nat Commun, 2016; 7:12263.

33.

Kummer

, Abbott

, Kratochvil

, et al. OctoMag: an electromagnetic system for 5-DOF wireless micromanipulation. In: IEEE International Conference on Robotics and Automation (ICRA) May 3–7, 2010, pp. 1610–1616.

34.

Fundueanu

, Constantin

, Ascenzi

. Poly(N-isopropylacrylamide-co-acrylamide) cross-linked thermoresponsive microspheres obtained from preformed polymers: influence of the physico-chemical characteristics of drugs on their release profiles. Acta Biomater, 2009; 5:363–373.

35.

Takaisi

. Note on the drag on a circular cylinder moving with low speeds in a semi-infinite viscous liquid bounded by a plane wall. J Phys Soc Japan, 1956; 11:1004–1008.

36.

Champmartin

, Ambari

, Roussel

. Flow around a confined rotating cylinder at small Reynolds number. Phys Fluids, 2007; 19:103101–103109.

37.

Abbott

, Peyer

, Lagomarsino

et al. How should microrobots swim?. Int J Rob Res, 2009; 28:1434–1447.

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Matryoshka-Inspired Micro-Origami Capsules to Enhance Loading,Encapsulation,and Transport of Drugs

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