Transcript Chapter 1
Chapter 4
Molecules in Biomaterials and Tissue
Engineering
Biomaterials
Applications
Ceramics
Aluminum oxide
Carbon
Hydroxyapatite
Dental and orthopedic
Composites
Carbon-carbon fibers
and matrices
Heart valves and joint implants
Metals - Atoms
Aluminum, Chrome, Cobalt, Gold,
Iridium, Iron, Manganese, Molybdenum,
Nickel, Niobium, Palladium, Platinum,
Tantalum, Titanium, Tungsten,
Vanadium, Zirconium
Metallic alloys
wide variety using metallic atoms
Joint replacement components,
fracture fixation, dental implants,
pacemakers, suture wires,
implantable electrodes
Polymers
Nylon
Synthetic rubber
Crystalline polymers
Replacement of soft tissues: skin,
blood vessels, cartilage, ocular lens,
sutures
Orthopedic
Table 4.1 Classification of biomaterials in terms of their base structure and some of their
most common applications.
Figure 4.1 These titanium-alloy joint replacements are an example of the many
applications for metal biomaterials for implantations. (from
http://www.spirebiomedical.com)
Figure 4.2 Polymers are made up of many monomers. This is the monomer for
poly(ethylene), a common biomaterial used for medical tubing and many other
applications.
Biomedical polymer
Poly(ethylene) (PE)
Low density (LDPE)
High density (HDPE)
Ultra high molecular weight
(UHMWPE)
Application
Bags, tubing
Nonwoven fabric, catheter
Orthopedic and facial implants
Poly(methyl methacrylate) (PMMA)
Intraocular lens, dentures, bone cement
Poly(vinyl chloride) (PVC)
Blood bags, catheters, cannulae
Poly(ethylene terephthalate) (PET)
Artificial vascular graft, sutures,
heart valves
Poly(esters)
Bioresorbable sutures, surgical
products, controlled drug release
Poly(amides) (Nylons)
Catheters, sutures
Poly(urethanes) (PU)
Coat implants, film, tubing
Table 4.2 The clinical uses of some of the most common biomedical polymers relate
to their chemical structure and physical properties.
Figure 4.3 This artificial heart valve is coated with Silizone, a biocompatible
material that allows the body to accept the implant. (from
http://www.sjm.com/devices/).
Biological system
Example of application
Blood
Hematopoietic (production of red blood
cells by) stem cells culture
Cardiovascular
Endothelialized synthetic vascular
grafts (angiogenesis)
Regeneration of the arterial wall
Compliant vascular prostheses
Liver and pancreas
Bioartificial pancreatic islets
Bioartificial liver
Musculoskeletal
Cartilage reconstruction
Bone reconstruction
Neural
Neurotransmitter-secreting cells
(polymer-encapsulated)
Neural circuits and biosensors
Peripheral nerve regeneration
Skin
Bioartificial skin substitutes
Table 4.3 Some examples of current applications in tissue engineering. Not all of
the listed applications are at the same developmental stage.
Electron
source
Condenser
Sample
Figure 4.4 (a) TEM microscope. The
electron beam passes through the sample,
generating on the fluorescent screen a
projected image of the sample, which can be
recorded by photographic means.
Objective
Projector
Fluorescent screen
Electron
source
Condenser
Condenser
Condenser
Deflector
CRT
Detector
Sample
Figure 4.4 (b) SEM microscope. Condenser
lenses focus the electron beam on the specimen
surface leading to secondary electron emission
that is captured by the detector and visualized on
the CRT screen. Both TEM and SEM operate in a
particle free (vacuum) environment.
Incident beam
(primary electrons)
Secondary
electrons
Backscattered
electrons
Figure 4.5 Principle of SEM operation. An incident beam of primary electrons displaces
orbital electrons from the sample atoms resulting in secondary electron emission which is
detected for image formation. Some primary electrons pass by the nucleus to become
backscattered electrons.
Figure 4.6 (a) An STM probe tip made of tungsten magnified 4,000 times. The tip is
very small, and can be ruined on a sample, which is seen in Figure 4.6 (b). (from
http://www.orc.soton.ac.uk/~wsb/photos.htm).
A
B
The assembly A slides
inside the assembly B,
driven by the Zapproach drive piezo.
Sliding
surfaces
Z-approach
drive piezo
Scanner
piezo
Sample
holder cage
Figure 4.7 This is a sample of a piezotube. There are different approaches, but all
use the same method of two opposing piezoelectric materials to move the sample
in each axis. (from http://www.topac.com/l).
Figure 4.8 STM schematics. The tip of a probe scans the surface of the sample. Three
dimensional movements of the sample under the tip are accomplished using a voltagecontrolled piezoscanner. The tunneling current crossing from the sample to the tip is further
processed leading to a topographical image.
Figure 4.9 Sketch of an SFM. A laser beam is focused on the cantilever, and reflected back to
a two-segment photodetector. The difference in output from each segment is proportional to
the deflection amplitude of the cantilever scanning the sample.
X-ray photon
(a)
Photoelectron
(b)
(c) Fluorescent radiation
(d)
Auger electron
Figure 4.10 When an X-ray photon (a) interacts with an atomic orbital electron of the sample, a
photoelectron (b) is emitted. The now unstable atom must relax to the ground state. The relaxation
process can be accomplished by either of two mechanisms: (1) an outer orbital electron releases energy
as fluorescent radiation (c) while occupying the place of the emitted photoelectron, or (2) the excess
energy is used to unbind and emit another outer orbital electron called an Auger electron (d). These
mechanisms operate for different sample depths, yielding the Auger electron emission characteristic of
the outermost surface of the sample.
Intensity (%)
100
0
Binding energy (eV)
1000
Figure 4.11 A typical XPS spectrum, showing photoelectron intensity as a
function of binding energy. Each peak may correspond to a distinct element of the
periodic table or to different orbital electrons of the same element. Some peaks
may also represent Auger radiation.
X-ray source
Retarding grid
Sample holder
Hemispherical
electrostatic
analyzer
Display
Data
processor
Detector
Slit
Figure 4.12 Basic schematics of an XPS instrument. An X-ray beam strikes the sample surface, giving
photoelectron radiation. These electrons enter the hemispherical analyzer where they are spatially
dispersed due to the effects of the retarding grid and of the electrostatic field of the concentric
hemispheres. Ramping voltages at the retarding grid allow kinetic energy scanning. At the other end of
the analyzer electrons are detected, counted, and a spectrum of photoelectron intensity versus binding
energy is displayed.
Hemispherical
Analyser
Spectroscopy
Detector
Lenses
Imaging
Detector
Irises
X-rays
Sample
Camera
Zoom
Microscope
Figure 4.13 Photograph (from
www.thermo.com/eThermo/CDA/Products/Product_Detail/1,1075,15885-158-X-11,00.html) and schematics of an ESCALAB. This iXPS instrument offers the capability of
parallel imaging, which obtains positional information from dispersion characteristics of
the hemispherical analyser and produces photoelecton images with spatial resolution better
than 5 m.
Figure 4.14 Schematic diagram of a SIMS instrument. Bombardment of primary ions on
the sample surface leads to secondary ion emission. A mass analyzer separates these ions in
terms of their mass-to-charge ratio. The ion detector converts this ionic current into an
electrical signal for further processing. The display presents the SIMS spectra, consisting of
the count of ions versus their mass-to-charge ratio.
Infrared
detector
Sliding
mirror
Beamsplitter
Source
Fixed mirror
Figure 4.15 Michelson interferometer. A beamsplitter transmits half of the source radiation to the
fixed mirror and the other half to the sliding mirror. A phase difference between the beams can be
induced by sliding the mirror causing detection of the two beams at different times. The detector
provides the interferogram, a plot of energy as a function of differences in optical paths. Beams
have been slightly shifted in the drawing to allow easy following of their path.
c
s
Figure 4.16 When an incident beam traveling at an angle in a medium of
refractive index c encounters another medium of refractive index s, it will
reflect in a direction given by and refract in the direction given by , verifying
Snell’s Law of Refraction.
LV
SV
SL
Figure 4.17 Surface tension components of a three-phase system to limit the
spread of a drop on top of a surface. is the interfacial free energy for each of the
phases. is the contact angle.
Figure 4.18 The amino acid molecule. To a central carbon atom, an amino group,
a carboxyl group and a hydrogen atom are bonded. R represents the rest of the
molecule, which is different for each of the 20 amino acids.
1
G() = <I(t) I(t + )>
G() = ACF
I(t) = intensity at time t
I(t + ) = intensity at (t + )
G()
= delay time
< > = time average
0
Figure 4.19 The autocorrelation function G() is 1 when two signals have delay
time = 0, then decays to 0 for long delay time.