The use of electric fields in tissue engineering: A review

doi:10.4161/org.5799

. 2008 Jan;4(1):11-7.

doi: 10.4161/org.5799.

The use of electric fields in tissue engineering: A review

Gerard H Markx¹

Affiliations

PMID: 19279709
PMCID: PMC2634173
DOI: 10.4161/org.5799

The use of electric fields in tissue engineering: A review

Gerard H Markx. Organogenesis. 2008 Jan.

. 2008 Jan;4(1):11-7.

doi: 10.4161/org.5799.

Author

Gerard H Markx¹

Affiliation

¹ School of Engineering and Physical Sciences; Heriot-Watt University; Riccarton; Edinburgh, Scotland, UK.

PMID: 19279709
PMCID: PMC2634173
DOI: 10.4161/org.5799

Abstract

The use of electric fields for measuring cell and tissue properties has a long history. However, the exploration of the use of electric fields in tissue engineering is only very recent. A review is given of the various methods by which electric fields may be used in tissue engineering, concentrating on the assembly of artificial tissues from its component cells using electrokinetics. A comparison is made of electrokinetic techniques with other physical cell manipulation techniques which can be used in the construction of artificial tissues.

Keywords: dielectrophoresis; electric field; electrokinetics; microenvironment; polarity; tissue engineering.

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Figures

**Figure 1**
Capacitance measurement of cell concentrations in tissue constructs. (A) Capacitance at 0.4 MHz of fibroblasts cells at different concentrations in a fibrin gel, showing a linear relation between capacitance and cell concentration. (B) Constantly monitoring the capacitance at 0.4 MHz allows the cell concentration in the artificial tissue to be followed in time. The gel was inoculated with 100.000 human fibroblast cells/ml in DMEM growth medium with 10% fetal calf serum. Capacitance measurements were performed with an Aber Instruments model 220 Biomass Monitor (Aber Instruments, Aberystwyth, UK).

**Figure 2**
Electro-orientation of (fission) yeast cells. The electrodes used had a spacing and width of 40 µm; the applied voltage was 10 V peak-to-peak. (A) Orientation along electric field lines at 1 MHz; (B) Orientation perpendicular to electric field at 50 MHz.

**Figure 3**
Outline of the principle of an electro-rotation setup, with the phases of the electric field signal applied to each electrode. The electro-rotation method can be used for orienting polarized cells in any desired direction.

**Figure 4**
Principle of dielectrophoresis. The dashed lines represent electric field lines. A dipole is induced by the electric field in the particle, and a force is exerted on the induced charges on both sides of the particle. Because the electric field strength is stronger near the smaller electrode on the right than near the larger electrode on the left the particle will experience a net force, pulling the particle towards the smaller electrode. If the charges on the electrodes are reversed the distribution of charges in the dipole will also reverse; dielectrophoresis will therefore occur in both AC and DC electric fields. If the surrounding medium is more polarisable than the particle the net force will be in the opposite direction (negative dielectrophoresis rather than the positive dielectrophoresis depicted in Figure 4).

**Figure 5**
Artificial haematopoietic stem cell microniches created using dielectrophoresis. (A) Top view; (B) side view; (C) actual aggregate. The aggregate shown is made from successive layers of osteoblast (bottom), stromal (middle) and Jurkat (top) cells, attracted between interdigitated oppositely castellated electrodes. The aggregates, which are approximately 500 µm across, mimic the osteoblast haematopoietic stem cell niche in bone marrow. Vascular haematopoietic stem cell niches, which include endothelial cells, can be created using a similar approach.

**Figure 6**
Textiles can be created which can be used for constructing cellular arrays using dielectrophoresis on large scale.

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References

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[1] Pethig R, Kell DB. The passive electrical properties of biological systems: their significance in physiology, biophysics and biotechnology. Phys Med Biol. 1987;32:933–970. - PubMed

[2] Pethig R, Kell DB. The passive electrical properties of biological systems: their significance in physiology, biophysics and biotechnology. Phys Med Biol. 1987;32:933–970. - PubMed

[3] Gabriel S, Lau RW, Gabriel C. The dielectric properties of biological tissues, 2. Measurements in the frequency range 10 Hz to 20 GHz. Phys Med Biol. 1996;41:2251–2269. - PubMed

[4] Gabriel S, Lau RW, Gabriel C. The dielectric properties of biological tissues, 2. Measurements in the frequency range 10 Hz to 20 GHz. Phys Med Biol. 1996;41:2251–2269. - PubMed

[5] Foster KR, Schwan HP. Dielectric properties of tissues and biological materials: a critical review. CRC Crit Rev Biomed Eng. 1989;17:25–104. - PubMed

[6] Foster KR, Schwan HP. Dielectric properties of tissues and biological materials: a critical review. CRC Crit Rev Biomed Eng. 1989;17:25–104. - PubMed

[7] Alanen E, Lahtinen T, Nuutinen J. Measurement of dielectric properties of subcutaneous fat with open-ended coaxial sensors. Phys Med Biol. 1998;43:475–485. - PubMed

[8] Alanen E, Lahtinen T, Nuutinen J. Measurement of dielectric properties of subcutaneous fat with open-ended coaxial sensors. Phys Med Biol. 1998;43:475–485. - PubMed

[9] Raicu V, Saibara T, Irimajiri A. Multifrequency method for dielectric monitoring of cold-preserved organs. Phys Med Biol. 2000;45:1397–1407. - PubMed

[10] Raicu V, Saibara T, Irimajiri A. Multifrequency method for dielectric monitoring of cold-preserved organs. Phys Med Biol. 2000;45:1397–1407. - PubMed

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The use of electric fields in tissue engineering: A review

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The use of electric fields in tissue engineering: A review

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