Synchronization of cellular contractions in the arteriolar wall

Jens Christian Brings Jacobsen; Bjørn Olav Hald; Jens Christian Brasen; Niels-Henrik von Holstein-Rathlou

Synchronization of cellular contractions in the arteriolar wall

Jens Christian Brings Jacobsen, Bjørn Olav Hald, Jens Christian Brasen, Niels-Henrik von Holstein-Rathlou

Renal and Vascular Research

Abstract

With few exceptions all tissues in the mammalian body are invested by a highly branched microcirculatory network. The microcirculation serves to bring the blood into close contact with every part of the tissue. In this way the exchange between blood and tissue of oxygen, nutrients, metabolic bi-products, etc. can be bridged efficiently by diffusion. Like most other hollow structures in the body, the wall of arterioles and small muscular arteries (resistance vessels) are invested with a specific kind of contractile cell known as the smooth muscle cell(SMC). The SMC is long and spindle shaped. Under the microscope its interior does not appear as highly organized as, for instance, the cells of skeletal muscle tissue. In the latter kind of cells the structure of the contractile machinery can be directly observed, but this is not the case for the SMC. In addition, contraction or relaxation of the SMC is involuntary, i.e. we cannot control it by will. For a number of reasons, however, the contractile characteristics of the SMC make it well suited to participate in the regulation of our internal milieu.

Original language	English
Title of host publication	Biosimulation in biomedical research, health care and drug development biosimulation in Biomedical Research, Health Care and Drug Development
Editors	Erik Mosekilde, Olga Sosnovtseva, Amin Rostami-Hodjegan
Number of pages	18
Publisher	Springer
Publication date	1 Jan 2012
Pages	219-236
Chapter	10
ISBN (Print)	978-3-7091-0417-0
Publication status	Published - 1 Jan 2012

Access to Document

Synchronization of Cellular Contractions in the Arteriolar WallFinal published version, 438 KB

http://www.springer.com/biomed/pharmaceutical+science/book/978-3-7091-0417-0

Cite this

Jacobsen, J. C. B., Hald, B. O., Brasen, J. C., & von Holstein-Rathlou, N.-H. (2012). Synchronization of cellular contractions in the arteriolar wall. In E. Mosekilde, O. Sosnovtseva, & A. Rostami-Hodjegan (Eds.), Biosimulation in biomedical research, health care and drug development biosimulation in Biomedical Research, Health Care and Drug Development (pp. 219-236). Springer. http://www.springer.com/biomed/pharmaceutical+science/book/978-3-7091-0417-0

Synchronization of cellular contractions in the arteriolar wall. / Jacobsen, Jens Christian Brings; Hald, Bjørn Olav; Brasen, Jens Christian et al.
Biosimulation in biomedical research, health care and drug development biosimulation in Biomedical Research, Health Care and Drug Development. ed. / Erik Mosekilde; Olga Sosnovtseva; Amin Rostami-Hodjegan. Springer, 2012. p. 219-236.

Research output: Chapter in Book/Report/Conference proceeding › Book chapter › Research › peer-review

Jacobsen, JCB, Hald, BO, Brasen, JC & von Holstein-Rathlou, N-H 2012, Synchronization of cellular contractions in the arteriolar wall. in E Mosekilde, O Sosnovtseva & A Rostami-Hodjegan (eds), Biosimulation in biomedical research, health care and drug development biosimulation in Biomedical Research, Health Care and Drug Development. Springer, pp. 219-236. <http://www.springer.com/biomed/pharmaceutical+science/book/978-3-7091-0417-0>

Jacobsen, Jens Christian Brings ; Hald, Bjørn Olav ; Brasen, Jens Christian et al. / Synchronization of cellular contractions in the arteriolar wall. Biosimulation in biomedical research, health care and drug development biosimulation in Biomedical Research, Health Care and Drug Development. editor / Erik Mosekilde ; Olga Sosnovtseva ; Amin Rostami-Hodjegan. Springer, 2012. pp. 219-236

@inbook{0dd241d68b3841ef98b65277ac5d84f8,

title = "Synchronization of cellular contractions in the arteriolar wall",

abstract = "With few exceptions all tissues in the mammalian body are invested by a highly branched microcirculatory network. The microcirculation serves to bring the blood into close contact with every part of the tissue. In this way the exchange between blood and tissue of oxygen, nutrients, metabolic bi-products, etc. can be bridged efficiently by diffusion. Like most other hollow structures in the body, the wall of arterioles and small muscular arteries (resistance vessels) are invested with a specific kind of contractile cell known as the smooth muscle cell(SMC). The SMC is long and spindle shaped. Under the microscope its interior does not appear as highly organized as, for instance, the cells of skeletal muscle tissue. In the latter kind of cells the structure of the contractile machinery can be directly observed, but this is not the case for the SMC. In addition, contraction or relaxation of the SMC is involuntary, i.e. we cannot control it by will. For a number of reasons, however, the contractile characteristics of the SMC make it well suited to participate in the regulation of our internal milieu.",

author = "Jacobsen, {Jens Christian Brings} and Hald, {Bj{\o}rn Olav} and Brasen, {Jens Christian} and {von Holstein-Rathlou}, Niels-Henrik",

year = "2012",

month = jan,

day = "1",

language = "English",

isbn = "978-3-7091-0417-0",

pages = "219--236",

editor = "Erik Mosekilde and Olga Sosnovtseva and Amin Rostami-Hodjegan",

booktitle = "Biosimulation in biomedical research, health care and drug development biosimulation in Biomedical Research, Health Care and Drug Development",

publisher = "Springer",

}

TY - CHAP

T1 - Synchronization of cellular contractions in the arteriolar wall

AU - Jacobsen, Jens Christian Brings

AU - Hald, Bjørn Olav

AU - Brasen, Jens Christian

AU - von Holstein-Rathlou, Niels-Henrik

PY - 2012/1/1

Y1 - 2012/1/1

N2 - With few exceptions all tissues in the mammalian body are invested by a highly branched microcirculatory network. The microcirculation serves to bring the blood into close contact with every part of the tissue. In this way the exchange between blood and tissue of oxygen, nutrients, metabolic bi-products, etc. can be bridged efficiently by diffusion. Like most other hollow structures in the body, the wall of arterioles and small muscular arteries (resistance vessels) are invested with a specific kind of contractile cell known as the smooth muscle cell(SMC). The SMC is long and spindle shaped. Under the microscope its interior does not appear as highly organized as, for instance, the cells of skeletal muscle tissue. In the latter kind of cells the structure of the contractile machinery can be directly observed, but this is not the case for the SMC. In addition, contraction or relaxation of the SMC is involuntary, i.e. we cannot control it by will. For a number of reasons, however, the contractile characteristics of the SMC make it well suited to participate in the regulation of our internal milieu.

AB - With few exceptions all tissues in the mammalian body are invested by a highly branched microcirculatory network. The microcirculation serves to bring the blood into close contact with every part of the tissue. In this way the exchange between blood and tissue of oxygen, nutrients, metabolic bi-products, etc. can be bridged efficiently by diffusion. Like most other hollow structures in the body, the wall of arterioles and small muscular arteries (resistance vessels) are invested with a specific kind of contractile cell known as the smooth muscle cell(SMC). The SMC is long and spindle shaped. Under the microscope its interior does not appear as highly organized as, for instance, the cells of skeletal muscle tissue. In the latter kind of cells the structure of the contractile machinery can be directly observed, but this is not the case for the SMC. In addition, contraction or relaxation of the SMC is involuntary, i.e. we cannot control it by will. For a number of reasons, however, the contractile characteristics of the SMC make it well suited to participate in the regulation of our internal milieu.

M3 - Book chapter

SN - 978-3-7091-0417-0

SP - 219

EP - 236

BT - Biosimulation in biomedical research, health care and drug development biosimulation in Biomedical Research, Health Care and Drug Development

A2 - Mosekilde, Erik

A2 - Sosnovtseva, Olga

A2 - Rostami-Hodjegan, Amin

PB - Springer

ER -

Synchronization of cellular contractions in the arteriolar wall

Abstract

Access to Document

Fingerprint

Cite this