Class 8 Pumps and Tubes PDF

Summary

This document is a lesson on circulatory systems, explaining the physical and physiological reasons behind their diversity in different species and how small-scale flow connects to large-scale flow in circulatory systems. It examines how evolution and physics intersect in the development of hearts. Includes diagrams of various types of circulatory systems.

Full Transcript

Pumps and Tubes Class 8
What are some of the physical and physiological
reasons for the evolutionary diversity of circulatory
systems?

How do the processes of small scale flow connect
to large scale flow in the operation and function of
circulatory systems?

How do evolution and physics intersect in the
development of hearts?

www.vanderbilt.edu/hillyerlab/Research__Circulation.html s1113.photobucket.com
 Pumps and Tubes
What are some of the physical and physiological reasons for the
evolutionary diversity of circulatory systems?

www.vanderbilt.edu/hillyerlab/Research__Circulation.html s1113.photobucket.com
 Why do animals need a heart?
Do all animals have one?

Diffusion is only effective at very small scales,
for larger scale molecule movement we need
bulk flow

bulk ow = uid movement caused by pressure gradients

Organisms need bulk flow….
To deliver key nutrients to every single part of the body.
To remove wastes from every single part of the body.

cdn.society6.com
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 Phylum Cnidaria
Body nutrient squeezers:
animals without hearts

Are they limited?

Evolutionarily constrained? Phylum Cnid
Why do organisms need bulk flow?

Animals
To deliver key nutrients to every single partwith
of theabody.
large surface area
To remove wastes from every single part of the body.
and a lot of muscular movements….
at happens when nutrients are not delivered and wastes are not removed?
areThis
The part without delivery dies. doing great without a
is serious! heart!

Phylum Phylum Platyhelmint
Body nutrient squeezers: animals without hearts
Platyhelminthes
Are they limited? Evolutionarily constrained?

Otherwise….
make a dedicated pump!!!

2015 16 2/3/2015
www.ucmp.berkeley.edu
OPEN CIRCULATORY SYSTEM
Phylum Arthropoda
Pumping tubes generate the flow

en.wikipedia.org

At the periphery, the blood ows freely
into the interstitial space between the shell and the organs.
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The circulatory fluid in open circulatory systems, called hemolymph,
is pumped by the heart though vessels but then exits the vessels into a
body cavity where it directly bathes the organs for nutrient

As the heart beats and
the animal moves,
the hemolymph circulates
around the organs
within the body cavity and
then reenters the heart.

https://commons.wikimedia.org/wiki/File:Open_circulatory_system.svg

Hemolymph returns to the blood
vessel through openings
called ostia.
 Open circulatory system

What are the disadvantages?
The open peripheral system limits
the size of the animals (insects and
spiders), because the interstitial
diffusion is efficient only over short
distances.

What are the advantages?
Despite the low pressure
of the open systems,
by lowering the resistance
the flow rate increases rapidly.

en.wikipedia.org
 Blood ow through the tissues of an insect is principally
through lacunae and sinuses.
In general, the blood of insects lacks a respiratory pigment.

The modest development of the
circulatory system in insects
seems paradoxical at rst.

Insects
have a lesson to teach:
the circulatory system can
remain quite simple in even
highly active animals
if it doesn’t have
the burden of O2 transport.

(From J. C. Jones. 1964. In M. Rockstein [ed.], The Physiology of Insecta, vol.3, pp. 1-107. Academic Press, New York.)
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 Let’s close up the pipes….
Annelida Philum
Closed circulatory system

Multiple
pseudo-hearts

These pseudohearts don't pump blood, but rather squeeze
vessels to help circulate blood throughout the worm's body weed-science-classes.wikispaces.com; en.wikipedia.org
 Closed circulatory system What are the disadvantages?

In a closed system, the blood is required to
travel through exceedingly small diameter
vessels to complete its circuit through the
body. These tiny vessels present a high
resistance to ow. Thus, in a closed system,
for blood to circulate at high rates, large
pressure di erences are required.

What are the advantages?

With a closed circulatory system, the spatial distribution of blood ow can be
nely controlled on very short timescales.
It is more e cient in that it uses less blood for even higher and faster levels of
distribution, supporting higher metabolisms and physical activities.

weed-science-classes.wikispaces.com; en.wikipedia.org
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 Pumps and Tubes
How do the processes of small scale flow connect to large scale flow in the
operation and function of circulatory systems?

www.vanderbilt.edu/hillyerlab/Research__Circulation.html s1113.photobucket.com
 General characteristics of circulatory systems

The three important components:

Pump/s or other propulsive structures to drive uid ow

A system of tubes, channels or other spaces through which the uid can ow

A uid that circulates through the system
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 The physics of ow through tubes: Ohm’s law

Ohm’s law ΔP = Flow x Resistance
V = IR
Electrical current: a ow of charged particles Flow of blood in the bloodstream.
Electrical potential di erence, the driving force for electrical current Pressure di erence
(ΔP) generated by the heart between arteries and veins.
Electrical resistance Hydraulic resistance

www.themeasureo ife.net
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 The key to circulation, however, lies in the tubes.

The arrangement of vessels in the organism
is influenced by general physical laws
as well as by specific physiological
requirements.

www.leememorial.org
 The physics of ow through tubes: Poiseuille’s law

What factors determine the resistance?

Ohm’s law 3 factors determine the resistance:
- viscosity of the blood
ΔP = Q x R - length of the vessel
Q = ΔP/R - radius of the blood vessel.

R= 8ηl/πr4

Flow increases with the fourth power of the radius!
Poiseuille's Law

If the radius of the lumen is reduced to a half what would be the change in the new rate of ow?

The rate of ow falls to 1⁄16 of the original rate!
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 The physics of ow through tubes: Poiseuille’s law

Poiseuille's Law
Ohm’s law Flow increases with
the fourth power of
Q = ΔP/R
the radius!

O2
Lungs Problem:
In the lungs and systemic tissues
Pump O2 is delivered by diffusion.
For an effective diffusion we need small tubes
O2
Tissue
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 In the lungs and systemic tissues
O2 is delivered by diffusion.
For an effective diffusion we need small tubes

Solution:
O2
Lungs Big tubes for delivery and
O2
small tubes for diffusion

…one more problem:
What happens when you place a
finger on the garden hose?
Pump

O2
Tissue
O2

VELOCITY OF WATER INCREASES!
For an effective diffusion we need both small tubes and low velocity of flow.
 The physics of ow through tubes: the principle of continuity

Flow in = Flow out

Q= A ∗ v

Q1=Q2
A1v1=A2v2
If the area of the tube decreases the speed of the fluid must increase.

Solution:
branching the vessels increases the total cross-sectional area!

boundless.com
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For an effective diffusion we need both small tubes and low velocity of flow!

The total cross-sectional
area of the vessels
increases with distance
from the heart.

Q= A ∗ v
Q1=Q2
A1v1=A2v2
Consequently, the
velocity of flow
decreases, and then
increases after passing
the capillaries.

boundless.com www.allaboutcircuits.com www.pdn.cam.ac.uk
Q = ΔP/R
What are the bene ts?
Lungs
Lungs

Pump
Pump

Tissue1

Tissue2

Tissue1 Tissue2 Tissue3
Tissue3

With tissues in parallele
we can change the pattern of flow by varying the relative resistances,
and we can reduce the pressure that has to be developed by the heart.
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 A physiological model involving a parallel circuit

We can change the pattern of flow by varying the relative
resistances of the different organs, by selectively
vasoconstricting or vasodilating the arterioles.

We can reduce the overall resistance of the circulation
(TPR).

www.pdn.cam.ac.uk www.pdn.cam.ac.uk Slideshare
 A physiological model involving a circuit in series

For a series resistance network, the total resistance (RT) equals the sum of the individual resistances.
Therefore, for the vessels depicted in the gure, the total resistance is equal to the sum of the small
artery (RA), arterioles (Ra), capillaries (Rc), venules (Rv), and vein (RV) resistances.

RT = RA + Ra + Rc + Rv + RV

The biggest drop in blood pressure in the circulation occurs across the vessels with
(collectively) the highest resistance: the arterioles.
This has considerable importance when you come to consider the control of the circulation.
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 Single vs double circulation

Single-Loop Circulation: blood passes
through the heart only once on each circuit

Double-loop circulation: are circulation systems
in which blood ows through the heart twice.

1 Heart vs 2 Hearts!

http://esi.stanford.edu/circulation/circulation6.htm
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 Pressure drops as it reaches High pressure to deliver blood to the tissues,
the tissues. and a low pressure to the lungs.

Lungs Lungs

Pump Pump1 Pump2

Tissues Tissues

What are advantages and disadvantages
of single vs double circulation?
In fish pressure drops as it reaches the systemic circulation.
In mammals we can have a high pressure to deliver blood to the peripheral tissues,
and a low pressure to the pulmonary circulation…and so we don’t blow out the lungs!
 Single vs double circulation

Tissues
Are lungs and tissues in series or in parallel?

In fish the two circuits are in series,
and so the flow through them
must be exactly the same
by the principle of continuity.

Tissues This is the same for a fully separated
4-chambered heart like mammals.

The difference is in the pressure!

http://esi.stanford.edu/circulation/circulation6.htm
 In Amphibians the blood is pumped
from a three-chambered heart with
two atria and a single ventricle.

The “two hearts” involves just a
single ventricle that produces
pressure for both the pulmonary
and systemic circulations.

The ow through the two circuits
depends on the resistance of each.
The resistance can be changed
independently for each circuit
through vasoconstriction.
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Most reptiles also have a three-chambered
heart that with a single ventricle produces
pressure for both the pulmonary and
systemic circulations.
Unique cardiac anatomy of crocodilians - a four-chambered heart with the dual aortic arch system
 Circulatory system of cephalopods (squids and octopus)
Figure 25.21 The circulatory plan of squids and octopuses (Part 1)

Physiologically the circulatory system of squids and octopus resembles that of
vertebrates more than other mollusks.
And the arrangement of hearts is closer to that in mammals than fish.
 ference is significant and must be considered when us (M. Hammer), who found it in a poorly ing three-dimensional (3D) structures within the genesis. A sep
comparing estimates of 'OH(n/'OH(s. For example, in referees; and the technical assistance of A. Clarke,
consolidated channel sandstone exposed in the concretion. Patterns of shapes and radiodensi- visible indicat

Downloa
upper half of the Hell Creek Formation (Maas- ties were found to resemble a four-chambered the geochemic
the model described in (8), 'OH(n/'OH(s & 1.00 R. Myers, T. Conway, P. Lang, and N. Paynter. trichtian) in Harding County, northwestern heart (Figs. 1 and 2). Two adjacent cavities been well stu

Case Study
when the boundary between the hemispheres is set
at the equator; this ratio decreases to 0.87 when the
Samples were obtained from PSA with assistance
from NOAA’s Carbon Cycle group. Supported side
South Dakota, USA. The extremities and left
in of theis skeleton were lost to erosion. The
surrounded by iron-rich walls are readily appar-
ent, connected to a dorsally arched tube in a
served in the p
preserved thro

www.prehistoric-wildlife
specimen otherwise very well preserved and position that is topologically appropriate for a whereby musc
Southern Hemisphere is defined as 8°N to 90°S (that part by the Atmospheric Chemistry project of the contains abundant evidence of tissues that usu- systemic aorta. The thicknesses of the walls de- conditions (12
ally decay, such as sternal ribs and cartilaginous limiting the cavities are consistent with those of The presum
is, when one additional model segment, 0° to 8°N, is NOAA Climate and Global Change Program. C.M.S. plates attached to caudal surfaces of thoracic ventricles and an interventricular septum, the re- the left ventric
included as being part of the Southern Hemisphere). acknowledges the support of NSF through grants ribs. The skeleton closely resembles that of the lative dimensions of which would vary with the 27 mm in diam
hypsilophodontid Thescelosaurus (6), and its degree of distension of the heart at death. The no indications
31. J. Rudolph, A. Khedim, R. Koppmann, B. Bonsang, J. NSF-ATM-9320778 and NSF-ATM-9903529. gracile dentary separates it from fragmentary atria are usually very thin-walled compared to aortic arch. If
Atmos. Chem. 22, 67 (1995). material of the closely related and sympatric the ventricles and often collapse at death, oblit- crocodiles, the
Bugenasaura (7). The circumference of the erating their internal cavities. They are not reli-
32. J. Rudolph, personal communication. 7 December 1999; accepted 10 March 2000 femur (197 mm) suggests a body weight of 300 ably discernable in the specimen, nor are the
kg (8), and the length of the femur (468 mm) small vessels that are expected in the region of
scales to a total body length of 3.9 m (9). A the putative heart base. A radiolucent area imme-

Downloaded from http://science.sciencemag.org/ on February 23, 2017
Cardiovascular Evidence for an
Intermediate or Higher
Metabolic Rate in an
Ornithischian Dinosaur
1*
Paul E. Fisher,. 1. Right lateral view of a 3D reconstruction Dale
of CT images Russell,2 specimen Fig. 2. Enlarged right lateral view of a 3D
A. Thescelosaurus
of the
owing the right (R) and left (L) ventricular3,cavities, preserved sternal4 ribs (S), and plates reconstruction
5 of CT images of the same spec-
embling uncinateMichael
processesK.(U)Stoskopf, Reeseribs.
attached to thoracic E. The
Barrick,
apex of Michael Hammer,
the heart has been imen showing the systemic arch (SA) and right
mporarily removed. Andrew A. Kuzmitz6 (R) and left (L) ventricular cavities.

Computerized tomography 21 APRIL
scans2000
of a VOL 288 SCIENCE
ferruginous www.sciencemag.org
concretion within the chest
Fig. 1. Right lateral view of a 3D reconstruction of CT images of the Thescelosaurus specimen Fig. 2. Enlarg
region of an ornithischian dinosaur reveal structures that are suggestive of a showing the right (R) and left (L) ventricular cavities, preserved sternal ribs (S), and plates
resembling uncinate processes (U) attached to thoracic ribs. The apex of the heart has been
reconstruction
imen showing
four-chambered heart and a single systemic aorta. The apparently derived temporarily removed. (R) and left (L)

condition of the cardiovascular system in turn suggests the existence of in- 504 21 APRIL 2000 VOL 288 SCIENCE www.sciencemag.org

termediate-to-high metabolic rates among dinosaurs.
Fossilized Heart Shakes Up Dinosaur Theories
The three-chambered heart of modern reptiles paired systemic aortas arising from the ventricle
(except crocodiles) includes a single ventricle and distributing blood to the body. In contrast,
Detailed,
that pumps blood both to thecomputerized
lungs and to the X-ray
the scansheart
four-chambered of the 66-million-year-old
of modern birds and fossilized heart
remainder of the body. In crocodiles, the ventri- mammals has two completely separated ventri-
show that its muscular
cle is composed of two chambers that are in- chambered-heart
cles and a single systemic may be similar
aorta, ensuring that to mammals and birds.
completely separated from each other function- only completely oxygenated blood is distributed
ally by the foramen of Panazzi. Thus, in all to the body. These modifications to the cardio-
 Pumps and Tubes
How do evolution and physics intersect in the development of hearts?

www.vanderbilt.edu/hillyerlab/Research__Circulation.html s1113.photobucket.com
 Why did the circulatory system evolve?

…most certainly evolved to
overcome the time and
distance constraints of
diffusion, thus permitting
increased body size and
metabolic rates

The movement of uid in blood
vascular systems was originally
mediated by the peristaltic motion,
but the appearance of true hearts in
which in ow and out ow are tightly
coupled via multiple chambers,
e cient electrical connection and
one-way valves would have helped
with the increased body size,
metabolic activity and the transition
from aquatic to terrestrial life.

Rita Monahan-Earley,Ann M. Dvorak, and William C. Aird, J Thromb Haemost. PMC 2017
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What do you need in order to build a biological heart?
Raise your hand when you have three key building blocks.

contracting cells

- Drosophila Tinman controls heart development.
- Mouse Nkx mutations cause cardiac defects.
- Amphioxus uses Nkx/Tinman homolog during
heart development.
- Nematodes (C. elegans) don’t have a heart, but
the pharynx contracts rhythmically using ceh-22
gene which is homologous to Nkx and Tinman.
- Nematodes with defective ceh-22 gene can have
mouse Nkx expressed and regain proper pharynx
function.
- Hydra (only have a gastrovascular cavity that
pumps fluids) express a gene related to Nkx at
location of pumping cells.

2/3/2015 en.wikipedia.org; 40
weinterrupt.com; nematode.unl.edu
 What do you need to build a biological heart?

- generation of positive and negative pressure

- development of heart maintains flow with different
mechanisms

- embryonic zebrafish use a suction pump before
valves develop

2/3/2015 ferris.edu; 41
linfishlab.webs.com
Forouhar et al (2006) Science
 What do you need to build a biological heart? Clas
- flow Guid

- Biomechanical forces of flow are necessary for Ho
cells to develop properly. op
- Initiation of heartbeat causes expression of Runx1
in blood stem cells; flow (shear stress) causes this W
expression and is necessary for correct heart div
development.
- Interruption of normal flow patterns causes cardiac Ho
defects.

Read

Key
surf
ope
hem
ostia
See the movies online: clos
http://www.nature.com/nature/journal/v421/n6919/suppinfo/nature01282.html syst
2/3/2015 ferris.edu; 42
linfishlab.webs.com Hove et al (2003) Nature; Adamo et al (2009) Nature
 Pumps and Tubes Class 8
What are some of the physical and physiological reasons for the
evolutionary diversity of circulatory systems?
Role of the Heart.
- Open vs Closed circulatory system
advantages and disadvantages

How do the processes of small scale flow connect to large scale flow in the
operation and function of circulatory systems?
- How to Build an efficient circulatory system
- Hagen–Poiseuille equation
- Principle of continuity
- Circuits in series vs in parallel

How do evolution and physics intersect in the development of hearts?
(Case studies)
- What you need to build a biological heart?
- Contracting cells; pressure gradient, flow.