Formation of elongated fascicle-inspired 3D tissues consisting of high-density, aligned cells using sacrificial outer molding

Neal, Devin; Sakar, Mahmut Selman; Ong, Lee-Ling Sharon; Asada, H. Harry

doi:10.1039/c4lc00023d

Cited by 58 publications

(71 citation statements)

References 32 publications

(40 reference statements)

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“…Nearly all machines require actuators, modules that convert energy into motion, to produce a measurable output in response to input stimuli. Efforts to manufacture bio-integrated actuators have targeted a range of cell types (5), including flagellated bacteria (6), cardiac muscle (7)(8)(9), and skeletal muscle (10)(11)(12). We previously demonstrated a millimeter-scale soft robotic device, or biobot, that uses the contractile force produced by electrically paced skeletal muscle to drive locomotion across a substrate (10).…”

mentioning

confidence: 99%

Optogenetic skeletal muscle-powered adaptive biological machines

Raman

Cvetkovic

Uzel

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

250

277

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Complex biological systems sense, process, and respond to their surroundings in real time. The ability of such systems to adapt their behavioral response to suit a range of dynamic environmental signals motivates the use of biological materials for other engineering applications. As a step toward forward engineering biological machines (bio-bots) capable of nonnatural functional behaviors, we created a modular light-controlled skeletal musclepowered bioactuator that can generate up to 300 μN (0.56 kPa) of active tension force in response to a noninvasive optical stimulus. When coupled to a 3D printed flexible bio-bot skeleton, these actuators drive directional locomotion (310 μm/s or 1.3 body lengths/min) and 2D rotational steering (2°/s) in a precisely targeted and controllable manner. The muscle actuators dynamically adapt to their surroundings by adjusting performance in response to "exercise" training stimuli. This demonstration sets the stage for developing multicellular bio-integrated machines and systems for a range of applications.bioactuator | stereolithography | tissue engineering | soft robotics U nderstanding complex biological systems requires uncovering the mechanisms through which integrated multicellular networks accomplish sensing, internal processing, and coordinated action in response to dynamic environmental signals. Attempting to reverse engineer these mechanisms for applications in regenerative medicine has been the focus of the burgeoning field of tissue engineering (1), and seminal advances in this field have targeted nearly every organ system in the body (2). These developments, in addition to improving the state of the art in therapeutics, have furthered our understanding of the design principles governing the organizational structure and function of natural biological systems. With this as a guide, we are ideally poised to start forward engineering biological machines, or bio-bots, capable of complex controllable nonnatural functional behaviors, thereby broadening the potential applications for building with biological materials.Before we can design bio-integrated machines for a range of applications, we must first engineer modular tissue building blocks that respond to external signals with complex functional behaviors. Observing and controlling the coordinated action of such building blocks in series and parallel will help us understand the emergent behavior of natural biological systems (3, 4). Nearly all machines require actuators, modules that convert energy into motion, to produce a measurable output in response to input stimuli. Efforts to manufacture bio-integrated actuators have targeted a range of cell types (5), including flagellated bacteria (6), cardiac muscle (7-9), and skeletal muscle (10-12). We previously demonstrated a millimeter-scale soft robotic device, or biobot, that uses the contractile force produced by electrically paced skeletal muscle to drive locomotion across a substrate (10). This bio-bot was the first demonstration of an untethered locomotive skeletal mu...

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mentioning

confidence: 99%

Optogenetic skeletal muscle-powered adaptive biological machines

Raman

Cvetkovic

Uzel

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

250

277

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“…4,5 In each case, recreating the complex function and structure of skeletal muscle in vivo is a challenging, but essential, consideration. Engineered tissues to date, however, have been characterized by a neonatal phenotype in terms of force production and structural maturity.…”

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confidence: 99%

Effects of Dexamethasone on Satellite Cells and Tissue Engineered Skeletal Muscle Units

Syverud

VanDusen

Larkin

2016

Tissue Engineering Part A

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Tissue engineered skeletal muscle has potential for application as a graft source for repairing soft tissue injuries, a model for testing pharmaceuticals, and a biomechanical actuator system for soft robots. However, engineered muscle to date has not produced forces comparable to native muscle, limiting its potential for repair and for use as an in vitro model for pharmaceutical testing. In this study, we examined the trophic effects of dexamethasone (DEX), a glucocorticoid that stimulates myoblast differentiation and fusion into myotubes, on our tissue engineered three-dimensional skeletal muscle units (SMUs). Using our established SMU fabrication protocol, muscle isolates were cultured with three experimental DEX concentrations (5, 10, and 25 nM) and compared to untreated controls. Following seeding onto a laminin-coated Sylgard substrate, the administration of DEX was initiated on day 0 or day 6 in growth medium or on day 9 after the switch to differentiation medium and was sustained until the completion of SMU fabrication. During this process, total cell proliferation was measured with a BrdU assay, and myogenesis and structural advancement of muscle cells were observed through immunostaining for MyoD, myogenin, desmin, and a-actinin. After SMU formation, isometric tetanic force production was measured to quantify function. The histological and functional assessment of the SMU showed that the administration of 10 nM DEX beginning on either day 0 or day 6 yielded optimal SMUs. These optimized SMUs exhibited formation of advanced sarcomeric structure and significant increases in myotube diameter and myotube fusion index, compared with untreated controls. Additionally, the optimized SMUs matured functionally, as indicated by a fivefold rise in force production. In conclusion, we have demonstrated that the addition of DEX to our process of engineering skeletal muscle tissue improves myogenesis, advances muscle structure, and increases force production in the resulting SMUs.

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“…38 Furthermore, testing of a large range of variations is possible under exactly adapted similar environmental conditions. However, except for an approach to establish fascicles in miniaturized size 39 there are up to now no published models for tendon or ligament on chip available.…”

Section: 25-28mentioning

confidence: 99%

Do There Exist Innovative Perspectives in Tissue Engineering-Based Ligament Reconstruction?

Tanzil¹

2017

ATROA

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Ligament reconstruction remains challenging, since ligaments represent heavily loaded tissues with high extracellular matrix (ECM) content, very low cell numbers, limited blood supply and as a consequence, restricted repair capacity. To circumvent limited auto graft availability and donor site morbidity, tissue engineered biological grafts could present benefit for ligament reconstruction in future. Valuable tissue engineered approaches can be developed based on small-scale in vitro models.This mini review was prepared to draw attention to some experimental key problems and to illustrate approaches to establish tissue engineered ligament substitutes including appropriate scaffolds, functionalization of them, applicable cell sources, three-dimensional (3D) cell culturing and seeding strategies. It opens also the view on novel perspectives, which could move ligament tissue engineering forward such as utilization of various natural allogenic and xengenic ligament-derived ECMs and first attempts in ligament bioprinting.

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Formation of elongated fascicle-inspired 3D tissues consisting of high-density, aligned cells using sacrificial outer molding

Cited by 58 publications

References 32 publications

Optogenetic skeletal muscle-powered adaptive biological machines

Optogenetic skeletal muscle-powered adaptive biological machines

Effects of Dexamethasone on Satellite Cells and Tissue Engineered Skeletal Muscle Units

Do There Exist Innovative Perspectives in Tissue Engineering-Based Ligament Reconstruction?

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