Remote Sensing Tutorial Introduction - Part 2 Page 26d


Nuclear medicine uses tomographic instruments to image body parts and functions by inserting radioisotopes into the vascular system and then seeking out concentrations of these tracers in various organs. SPECT and PET scanning are described, both producing tomographic images and/or individual slices. Other methods of examining exterior or interior parts of the body rely on thermal radiation (thermography) or acoustic waves (sonography). Endoscopic instruments with a light source and a camera at the imaging end are inserted into the body to take optical pictures of the throat, esophagus, stomach, lower intestines or, less commonly, other parts of the body.


Medical imaging is a mainstay in the field of nuclear medicine. In nuclear medicine, radioactive elements (as isotopes) that are part of specific fluids are introduced into the body (usually by injection into the blood). As it circulates, a particular radioisotope tends to distribute throughout the body at points served by the blood flow and may even concentrate preferentially in certain organs (for example, radioactive iodine in the thyroid gland). As the isotope decays, it gives off radiation (most commonly, gamma rays) which can be intercepted by a gamma camera or other detector. Variations in radiation intensity and in spatial location at point sources in the body activate film or more usually a detector array that responds by mapping the radiation intensity in X-Y space to create an image. The radioisotopes in normal usage have relatively short half lifes, thus decaying rapidly, and minimizing the exposure to damaging radiation.

One of the earlier techniques that uses radioisotopes is scintigraphy. Radioactive components, typically of such elements as iodine, techniceum, and thallium, are inserted into the body. After dispersion, as the isotope decays it emits gamma rays that are picked up by a gamma camera detector placed against the body in the area of interest. The buildup of scintillation light spots on the detector forms the image, that singles out location and intensity of the emitted rays over time. Here is a portable gamma camera capable of producing scintigrams:

A Gamma Camera Unit used to make scintigrams.

By selecting the proper radioisotope and getting it into the body so as to selectively concentrate in the bones, skeletal anomalies are readily imaged, as shown in this pair of whole body views:

Whole body scintigrams showing the human skeleton; black areas are suspicious anomalies.

One common use is in looking for anomalies in the thyroid gland. In this view of a cat, the scintigram pinpoints abnormal conditions (red/yellow) in this cat’s thyroid gland in which injected radioactive Iodine (I:sup:126) has selectively concentrated:

Evidence of a diseased thyroid in a cat.

Two high-powered imaging instruments in nuclear medicine which use the tomographic approach, and range in the same general size category and cost, are the SPECT (Single Photon Emission Computed Tomography) and the PET (Positron Emission Tomography) Scanners. These instruments are especially suited to monitoring dynamic processes such as blood flow and cell metabolism. We turn first to the SPECT instrument which preceded in general use the later PET technology.

Both instruments use a Gamma camera to detect gamma ray photons emitted from the radioisotopes used in imaging the body. A Gamma Camera is pictured below, and beneath it is a diagram that suggests its general operation:

|A stand-alone Gamma Camera. |

Schematic diagram through a Gamma Camera showing its functional components.

The signal - gamma ray photons - passes into the instrument through collimators and then strikes detectors made from thallium-activated sodium iodide crystals. The light spots created by the gamma rays are picked up by photomultipliers, amplified, and sent through decoding circuits that establish the X and Y positions of each spot. The signal is then reconstructed as an image. A full PET unit is depicted here:

A PET scanner.

The injected radioisotopes have different half lifes, depending on species, but all are in the multiple hour range. Normally used is Tc99 (Technicium), other radioisotopes include I123, and Xe133; all are gamma emitters. Each decay produces a single gamma ray photon. SPECT is most commonly applied to brain scans to determine abnormalities but it works on other organs such as the heart and with special handling can image bone anomalies. The next group of images shows some results from SPECT scans of the normal brain; first is a high quality head slice:

SPECT scan through the head

The image gray tones can be assigned colors in different ways to bring out certain features; note the terminology applied to different view directions - Transaxial; Sagitall; Coronal (what applies to the above image?):

A normal brain imaged from three positions, to which different color schemes have been imposed.

Here is a sequence of individual image slices (transaxial) through different levels of the brain.

SPECT image slices.

Now to examples of brain disorders that are revealed by anomalous patterns. The first shows the effects a stroke in a transaxial view; the second of depression, as seen in a sagittal orientation (differences in pattern from the normal state shown above are subtle and need a neurologist’s expertise to interpret); the third displays patterns found in a patient with Chronic Fatigue Syndrome (CFS; closely related to Fibromyalgia, an illness that has beset the writer [NMS] since 1970):

Tranaxial PET scan showing anomalous brain patterns resulting from a stroke.

PET scan of a patient with depression.

Brain pattern found in a PET scan slice that results from Chronic Fatique syndrome.

The specialized diagram below, developed from a SPECT scan, indicates changes in alchoholic disease before and after treatment

The effects of alcohol on certain areas of the brain, made from a patient undergoing treatment; the diagram is based on a PET scan.

This last pair, side by side, consists of colorized tomographic reconstructions of the brain using numerous slices. A normal brain appears on the left; the brain of a heroin addict in advanced deterioration is on the right. (This is a dramatic depiction of the brain’s deterioration that should be an effective warning in the “war against drugs”.)

3-D SPECT composite of a normal brain. 3-D SPECT composite of a brain in a heroin addict.

Since SPECT and CT are both tomographic methods (as is PET and MRI), computer-controlled image processing can combine results from two methods, as is illustrated in this SPECT-CT 3-D representation showing a human’s rib cage, spine, heart, and left kidney:

Registered SPECT and CT images of a human upper torso, showing both bones and internal organs.

Let’s now look at a more advanced instrument, the PET - these two Web sites offer details in the theory and practice of its use: Lawrence Berkeley Laboratory, and TRIUMF, the last a consortion of Canadian Universities engaged in radiation research. PET technology began to be applied in the 1950s but its more advanced capabilities did not “go on line” until the 1980s. Compared with SPECT, PET images have about a factor of four improvement in resolution; the instrument is notably more expensive (around $600000) and the cost of a PET scan typically is 3 times that of a SPECT scan.

Isotopes such a C11, N13, O15, and F18, part of liquid compounds such as glucose, are injected into the body and travel to various locations that include organs of interest. When these isotopes decay, they emit positrons that can then collide with electrons, producing gamma ray photons. In this nuclear reaction, two gamma rays result and are paired such as to move away from the nuclide in exactly opposite directions. Both gamma photons are sensed simultaneously by detectors (180°) apart. This double set of radiation photons improves detectability and resolution. This is a typical PET instrument:

Part of a PET instrument showing the cyclotron used to produce the short-lived radioisotopes.

What is interesting about this setup is the presence of a small cyclotron which bombards compounds containing the element(s) that will be used as tracers, thusly producing “fresh” radionuclides. These have half lifes that range from seconds to minutes so they must be inserted into the patient (who is in a ring with detectors in a chamber at the back side of the PET scanner) almost in real time as the tracer compound moves out of the cyclotron to the individual being diagnosed. PET scans are especially targeted to soft tissue examination, and are in use in neurology, cardiology, and tumor detection in various parts of the body. We start with three images that show a PET scan version of whole body imaging (compare with the scintigram above); in this case the progression of removal of malignant tissue by chemotherapy is being monitored.

Whole body PET scan; patient is receiving a F<sup>18</sup> radioisotope.

In this pair of images PET reveals the progression of a cancerous area in the left breast of a patient.

Cancerous growth in upper breast area as displayed in this color rendition of a PET scan image.

This series of PET slices shows the distribution in the brain of anomalous conditions (right side) associated with epilepsy.

Patterns in the brain related to elilepsy, indicated in this PET scan sequence.

A PET scan can show patterns in the brain which aid the physician in diagnosing and treating Parkinson’s Disease:

Parkinson's Disease patterns in the brain; PET scan images of normal brain and of a patient with PD before and after treatment.

This next group of images illustrates how sometimes an MRI will not clearly pinpoint an abnormality such as a lesion associated with Huntington’s disease which is displayed effectively by a PET scan

Sets of MRI images on the left and center; PET images on the right disclose a lesion in the brain of the same patient.

This last PET image pair highlights the results of an interesting research study by Dr. Marcus Raidle of Washington University (St. Louis). He took a PET scan of the brain of a volunteer that indicates on the top two areas where some rudimentary skill/knowledge functional activity has left its imprint. After that volunteer was trained over four months to modify this skill and develop new capabilities, the bottom PET image shows a shift to new areas where this ability has become stored in the brain.

PET scans of a human brain before and after it was involved in an extensive experimental retraining program.

We now leave tomography and nuclear medicine techniques to cover several more imaging methods using different approaches. One is just an application of thermal remote sensing - thermography, described on page 9-9 (the sensors in thermal cameras used in medical imaging operate respond to mid-infrared wavelengths between 2.8 and 5.5 µm). It is also known as Medical Infrared Imaging. Thermograms of the body simply indicate variations in temperature, which can be diagnostic for certain illnesses and pathologic conditions in which there is local heat inflammation. Most thermograms are made of the body exterior, in which the temperatures are that of the skin region; interior variations such as from local infections or muscle strain generate higher temperatures that result in heat flow to the body surface by direct conduction and through vascular transport. Medical thermography is limited by generally low image resolution but as it becomes more increasingly used with refined technology, it now serves as an inexpensive first look tool to determine if anomalies are present that warrant further imaging by more sensitive methods. Thermography is most often used in mammography, as an early detection method to be followed by an x-ray mammogram if significant abnormality is revealed. Here is a thermogram of an advanced tumor in a female breast.

|Thermogram of the chest of a female patient; the right breast shows a widespread warmer area related to a malignancy. |

In this view, the thermogram indicates inflammation of the lumbar and thoracic areas of a male patient’s back

Back abnormalities displayed as warmer inflammed area.

A muscle tear in the right leg of this male gives rise to heat and swelling, evident in this thermogram.

Right leg of male shows higher temperatures due to muscle damage.

This next thermogram shows a woman who is 8 months pregnant. Although no abnormality is indicated, it is interesting to realize that the womb is at a generally higher temperature to provide a better pre-natal environment.

|Side view of a pregnant woman in which the uterus at this 8 months stage is generally warmer than its surrounding. |

A thermogram can also depict abnormal cooling, such as from frost bite or from Raynauld’s Syndrome (contractions of smaller arteries in the extremeties, leading to less blood supply and thus lower temperatures), shown here:

Thermogram of hand of patient with Raynauld's Syndrome; note the fingers are much cooler.

A commonly used, and relatively inexpensive, imaging technology depends on acoustic or ultrasonic waves sent into the body where they are both refracted and reflected (this is an example of medical remote sensing that does not draw upon EM radiation). The result is a sonogram or echogram which to the layman appears fuzzy and limited in definition but is informative to the physician and trained technicians. A transducer that both generates acoustic waves and receives their reflections (echos) can be placed directly near the specific organ being investigated. The acoustic signal that passes through the body is between 1 and 10 MHz (3.5 to 7.0 MHz most frequently used). A brief summary of Ultrasonic imaging is found at the HowStuffWorks site. Once there additional information can be sought by clicking on “Lots More Information” and then on “Basic Concepts of Ultrasound” that gets you to “Diagnostic Ultrasound” by Beverly Stern of Yale University (putting on a direct link on this page fails to work). Both the text and the references on the HowStuffWorks site touch upon Doppler sonography and 3-D sonography.

A primary use of ultrasound is to monitor the progress of a pregnancy, making a timeline for growth stages, determining sex (around the 5th month), and watching for obvious abnormalities. The technique is quick, painless, non-invasive, and low cost. We show two typical sonograms, the top being at the 8 weeks and the bottom the 27 weeks stage:

Sonogram of a fetus 8 weeks after conception

Sonogram of a baby now in its 27th week of development.

Recent improvements in sonography allow remarkable 3-D images of the growing child in the womb to be reconstructed using a variant of tomography by integrating (with a computer program) images taken from different directions. Look at this set of images:

A series of 3-D images of a pre-natal child.

Another common use of ultrasound is to observe in real time the dynamic functions of the heart. An echocardiogram is obtained using the transducer to produce images on a screen that are continuously recorded to observe the movements of the major heart components. This is a typical (still) image, showing the left and right atrium and left and right ventricle:

image31

This echocardiogram presents the heart from a different perspective (note the faint trace in blue at bottom; this is an EKG display):

Four chambers of the heart imaged as an echocardiogram.

During the procedure, the heart is also monitored with an EKG (electrocardiogram). This measures electrical pulses associated with heart action. The diagnostic setup involves placing a number of patches that serve as electrodes at various points around the chest. A screen displays a series of regular (if no arrhythmias are occurring) pulses or spikes. This is a diagram that summarizes the procedure:

image33

EKG’s are among the most frequently performed diagnostic tests performed on patients to determine the status of their heart and their general health.

Our final consideration of medical imaging describes a general technique - endoscopy (click on this for a good Internet synopsis) - that is a “stretch” when trying to fit it into categories of remote sensing. Still, there is an active source of photons that sends out electromagnetic radiation to a target a small distance away and a sensor that picks up the return signal. In endoscopic procedures a long cable (made up of bundles of optical fibers) with a light and a camera lens situated at the interior viewing end that picks up the surface of the body’s interior is inserted, usually from the rectum into the bowel (colonoscopy or protoscopy) or from the mouth into throat and stomach (gastroscopy). The exterior end may have an ocular eyepiece and perhaps a small recording camera or the light signal may be sent to a screen display. This is what a typical endoscope looks like:

An endoscope.

The writer’s first experience with this scope was a search for a stomach ulcer (the doctor found three). By foreswearing the full dose of anesthesia, I remained conscious through the procedure (fascinated by the images on the TV screen and broke the staff up when I said the pictures of the stomach lining closely resembled the surface of Jupiter’s moon Io (check the Io images on page 19-16). This is a view of a gastric ulcer (not mine):

An ulcerated stomach.

The esophagus (a tube extending from the throat to the stomach) also is a site where problems can be detected by endoscopy. Here is a picture of a hiatal hernia in the esophagus, a primary condition which allows gastric reflux to occur more readily.

Endoscopic picture of a herniated esophagus.

Generally, a colonoscopy ranks lower in popularity among patients (despite the fact that one is usually sedated). The writer’s curiosity to see his colon led him to forego any anesthesia; the discomfort really wasn’t bad and the visual scenes during the traverse were rewarding. This is a view hat shows a colon with diffuse diverticular disease. Multiple small “out-pouchings” of the colon are evident. This is a condition brought about by nerniation of the colonic mucosa outwards at the sites of penetrating arteries which cause weak points in the colon wall.:

Colon with diffuse diverticulosis.

With this anal insert, we come to the “end” of this diversion into a vital offshoot of remote sensing that you will likely experience directly at some time(s) in your life. We have examined the more common types of medical remote sensing or imaging. Other instruments exist, some using different parts of the EM spectrum or other energy sources; new technology constantly improves the capabilities to examine mammalian physiology and pathology. Suffice to conclude that these applications of remote sensing are of greatest interest to humanity because they ameliorate our health and often save our lives.


Primary Author: Nicholas M. Short, Sr. email: nmshort@nationi.net