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Abstract

The tissue engineering community has been vocal regarding the need for noninvasive instruments to assess the development of tissue-engineered constructs. Medical imaging has helped fulfill this role. However, specimens allocated to a test tube for imaging cannot be tested for a prolonged period or returned to the incubator. Therefore, samples are essentially wasted due to potential contamination and transfer in a less than optimal growth environment. In turn, we present a standalone, miniature, magnetic resonance imaging-compatible incubator, termed the e-incubator. This incubator uses a microcontroller unit to automatically sense and regulate physiological conditions for tissue culture, thus allowing for concurrent tissue culture and evaluation. The e-incubator also offers an innovative scheme to study underlying mechanisms related to the structural and functional evolution of tissues. Importantly, it offers a key step toward enabling real-time testing of engineered tissues before human transplantation. For validation purposes, we cultured tissue-engineered bone constructs for 4 weeks to test the e-incubator. Importantly, this technology allows for visualizing the evolution of temporal and spatial morphogenesis. In turn, the e-incubator can filter deficient constructs, thereby increasing the success rate of implantation of tissue-engineered constructs, especially as construct design grows in levels of complexity to match the geometry and function of patients' unique needs.

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References

Shepherd

T.M.

, Blackband

S.J.

, and Wirth

E.D.

3rd . Simultaneous diffusion MRI measurements from multiple perfused rat hippocampal slices. Magn Reson Med, 48, 565, 2002.

, Othman

S.F.

, and Magin

R.L.

Monitoring tissue engineering using magnetic resonance imaging. J Biosci Bioeng, 106, 515, 2008.

Cho

, Wood

, and Bowlby

M.R.

Brain slices as models for neurodegenerative disease and screening platforms to identify novel therapeutics. Curr Neuropharmacol, 5, 19, 2007.

Lysaght

M.J.

, Jaklenec

, and Deweerd

Great expectations: private sector activity in tissue engineering, regenerative medicine, and stem cell therapeutics. Tissue Eng Part A, 14, 305, 2008.

Vunjak-Novakovic

Overview of tissue engineering. Presented at the Functional Imaging for Regenerative Medicine, Gaithersburg, MD, 2012.

Petersen

, Potter

, Butler

, Fishbein

K.W.

, Horton

, Spencer

R.G.S.

, and McFarland

E.W.

Bioreactor and probe system for magnetic resonance microimaging and spectroscopy of chondrocytes and neocartilage. Int J Imag Syst Tech, 8, 285, 1997.

Potter

, Sweet

D.E.

, Anderson

, Davis

G.R.

, Isogai

, Asamura

, Kusuhara

, and Landis

W.J.

Non-destructive studies of tissue-engineered phalanges by magnetic resonance microscopy and X-ray microtomography. Bone, 38, 350, 2006.

Chesnick

I.E.

, Avallone

F.A.

, Leapman

R.D.

, Landis

W.J.

, Eidelman

, and Potter

Evaluation of bioreactor-cultivated bone by magnetic resonance microscopy and FTIR microspectroscopy. Bone, 40, 904, 2007.

Laurencin

C.T.

, Khan

, Kofron

, El-Amin

, Botchwey

, Yu

, and Cooper

J.A.

Jr . The ABJS Nicolas Andry Award: tissue engineering of bone and ligament: a 15-year perspective. Clin Orthop Relat Res, 447, 221, 2006.

10.

Amini

A.R.

, Laurencin

C.T.

, and Nukavarapu

S.P.

Bone tissue engineering: recent advances and challenges. Crit Rev Biomed Eng, 40, 363, 2012.

11.

Tolar

, Nauta

A.J.

, Osborn

M.J.

, Panoskaltsis Mortari

, McElmurry

R.T.

, Bell

, Xia

, Zhou

, Riddle

, Schroeder

T.M.

, Westendorf

J.J.

, McIvor

R.S.

, Hogendoorn

P.C.

, Szuhai

, Oseth

, Hirsch

, Yant

S.R.

, Kay

M.A.

, Peister

, Prockop

D.J.

, Fibbe

W.E.

, and Blazar

B.R.

Sarcoma derived from cultured mesenchymal stem cells. Stem Cells, 25, 371, 2007.

12.

Tasso

, Augello

, Carida

, Postiglione

, Tibiletti

M.G.

, Bernasconi

, Astigiano

, Fais

, Truini

, Cancedda

, and Pennesi

Development of sarcomas in mice implanted with mesenchymal stem cells seeded onto bioscaffolds. Carcinogenesis, 30, 150, 2009.

13.

Aubin

J.E.

, and Triffitt

J.T.

Mesenchymal stem cells and osteoblast differentiation. In: Bilezikian

J.P.

, Raisz

L.G.

, and Rodan

G.A.

, eds. Principles of Bone Biology. San Diego, CA: Academic Press, 2002, p. 59.

14.

Kumar

, Mahendra

, and Ponnazhagan

Determination of osteoprogenitor-specific promoter activity in mouse mesenchymal stem cells by recombinant adeno-associated virus transduction. Biochim Biophys Acta, 1731, 95, 2005.

15.

Itonaga

, Sabokbar

, Sun

S.G.

, Kudo

, Danks

, Ferguson

, Fujikawa

, and Athanasou

N.A.

Transforming growth factor-beta induces osteoclast formation in the absence of RANKL. Bone, 34, 57, 2004.

16.

Takahashi

, Kato

, Suzuki

, Kawabata

, and Takagi

Autoregulatory mechanism of Runx2 through the expression of transcription factors and bone matrix proteins in multipotential mesenchymal cell line, ROB-C26. J Oral Sci, 47, 199, 2005.

17.

Frank

, Heim

, Jakob

, Barbero

, Schafer

, Bendik

, Dick

, Heberer

, and Martin

Real-time quantitative RT-PCR analysis of human bone marrow stromal cells during osteogenic differentiation in vitro. J Cell Biochem, 85, 737, 2002.

18.

Meinel

, Fajardo

, Hofmann

, Langer

, Chen

, Snyder

, Vunjak-Novakovic

, and Kaplan

Silk implants for the healing of critical size bone defects. Bone, 37, 688, 2005.

19.

, Othman

S.F.

, Hong

, Peptan

I.A.

, and Magin

R.L.

Magnetic resonance microscopy for monitoring osteogenesis in tissue-engineered construct in vitro. Phys Med Biol, 51, 719, 2006.

20.

Washburn

N.R.

, Weir

, Anderson

, and Potter

Bone formation in polymeric scaffolds evaluated by proton magnetic resonance microscopy and X-ray microtomography. J Biomed Mater Res Part A, 69, 738, 2004.

21.

Rockwood

D.N.

, Preda

R.C.

, Yucel

, Wang

, Lovett

M.L.

, and Kaplan

D.L.

Materials fabrication from Bombyx mori silk fibroin. Nat Protoc, 6, 1612, 2011.

22.

Mark

M.P.

, Prince

C.W.

, Gay

, Austin

R.L.

, Bhown

, Finkelman

R.D.

, and Butler

W.T.

A comparative immunocytochemical study on the subcellular distributions of 44 kDa bone phosphoprotein and bone gamma-carboxyglutamic acid (Gla)-containing protein in osteoblasts. J Bone Miner Res, 2, 337, 1987.

23.

McLeod

K.J.

, and Collazo

Suppression of a differentiation response in MC-3T3-E1 osteoblast-like cells by sustained, low-level, 30 Hz magnetic-field exposure. Radiat Res, 153, 706, 2000.

24.

Poppe

, Wysienski

, Slynarski

, Gajewski

, and Szukiewicz

Generating autogenous cartilage on the basis of subperichondrial grafts of demineralized bone matrix with local stimulation by growth factors. Ortop Traumatol Rehabil, 3, 190, 2001.

25.

Yucel

, Kose

G.T.

, and Hasirci

Tissue engineered, guided nerve tube consisting of aligned neural stem cells and astrocytes. Biomacromolecules, 11, 3584, 2010.

26.

Kim

, and Ma

Bioreactor strategy in bone tissue engineering: pre-culture and osteogenic differentiation under two flow configurations. Tissue Eng Part A, 18, 2354, 2012.

27.

Moinnes

J.J.

, Vidula

, Halim

, and Othman

S.F.

Ultrasound accelerated bone tissue engineering monitored with magnetic resonance microscopy. Conf Proc IEEE Eng Med Biol Soc 1, 484, 2006.

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The e -Incubator: A Magnetic Resonance Imaging-Compatible Mini Incubator

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