OK who hasn’t made rock candy as a kid? No? Give it a try. Maybe you have a little brother or sister you can impress. All you need is a super saturated solution of sugar, a surface for crystal nucleation (string), and lots of time…
Now what if you were to apply this technique to obtain crystals of DNA? I don’t suggest that you eat it as a treat but you could possibly try X-ray crystallography.
The challenge is that DNA, unlike proteins, is an exceedingly large molecule which does not lend itself to crystallisation. The result is a highly viscous suspension of spiderweb-like filaments. However, it is this very suspension that the DNA molecules were deduced to be neatly aligned alongside one another by studying the X-ray diffraction patterns. This initial challenge was successfully overcome by Rosalind Franklin. Her hard work then laid the ground work for Watson and Crick to piece together the puzzle of DNA structure (winning the 1962 Nobel Prize along with Wilkins).
Now the x-ray crystallography imaging technique is no pic-nic! It was first described by the Australian father-and-son duo William Henry Bragg and William Lawrence Bragg. Essentially x-rays are projected onto a crystalline solid and when analyzing the diffraction patterns it is possible to determine how its molecular atoms are positioned in relation to one another. This is due to x-rays having very short wave-lengths (see x-rays in the blog) and the mathematical analysis of predictable diffraction from the three dimensional structure of the crystal. It was Lawrence Bragg who developed the equation to describe this diffraction and is now known as Bragg’s Law. He and his father won the Nobel Prize for this work in 1915.
I used to listen to New Order back in the day and they are still singing (and dancing?) with a more recent release of Crystal by New Order. So, listen to the song while making rock candy and maybe you too will come up with a brilliant idea worthy of a Nobel Prize by the time the crystals are big enough to eat.
Now if you remember the rules:
1- I introduce and discuss a word.
2- You have to use the word in a sentence by the end of the day. No need to use it in the correct context – actually out of context is more fun and elicits a more entertaining response!
Today, we have to use “Bragg” in a sentence. Here are two examples to help you along:
MiWord of the Day is… Supernova!
So, what does medical imaging have to do with a Supernova? Well in the B-movie – Supernova a deep space medical ship responds to a distress signal from a nearby mining planet and gets too close to a Red Supergiant ready to go Supernova. Is your geek alert tingling?
Well, believe it or not Supernovas are explosions of giant stars. Nuclear fusion produces iron in the cores of these stars. Such dense matter at the core creates a tendency for the star to collapse on itself due to gravitational pull. This is kept in check by the massive amounts of energy the star is constantly releasing. But what happens when the star starts to run out of fuel? Yup, you guessed it. It collapses on itself and implodes. As the star rushes inwards, protons and electrons combine to produce neutrons that in turn collide with the core and produce a crazy big explosion. This sudden release of energy is accompanied by the production of x-rays. Yes, I am serious. What is left behind of the exploded star is either a neutron star or a black hole depending on the mass of the remains.
So, a supernova is essentially a giant x-ray machine? Maybe not. However, by studying these cosmic x-rays astronomers are able to help describe the structure of the universe (not Castle Greyskull). Cool.
Question for you: should we be concerned with being exposed to cosmic x-rays? No. Cosmic x-rays are pretty much completely filtered out by our atmosphere by the time they get to the surface. So, how do astronomers get readings? Good question. By placing their recording instruments on satellites and spacecraft, of course!
Now on to using supernova in a sentence today:
Serious example – So did you catch the last supernova in our galaxy? Happened about 400 years ago. No? The next one should be soon as it is overdue by about 300 years.
Less serious – Growing up I always loved the Chevy Nova SS. Especially when it was customized. It surely was a super Nova…
Enjoy Ray LaMontagne – Supernova to recover from today’s post and I’ll see you in the blogosphere.
Pascal Tyrrell
MiWord of the Day Is… Pentimenti!
What!!? Do you find it on pizza or in the middle of green olives? Well actually, it is a word of Italian origin and describes minor changes in a painting during its composition. So, similar to erasing some of your hand writing and then writing over it again with the corrected text. I guess for you younger folk it would be like pressing back-space and then re-typing! The difference of course is that there would NOT be any pentimenti as there would no trace of your previous attempt…
So what does this have to do with medical imaging? In our last Mi word of the day we talked about x-rays. Now, today we take x-rays and our ability to peer inside the human body for granted. So what else can we see with x-rays? Believe it or not x-rays can also help to reveal how a painting evolved from first brush strokes to finished product. X-ray analysis can help to describe the paint composition to the different layers that may exist in the painting.
Consider, for example, “Patch of Grass” by Van Gogh seen above. It was discovered by x-ray analysis that this 1887 painting completely concealed a portrait of a woman that Van Gogh had painted over. He often did this to save money on canvases (maybe to buy Absinthe – how naughty!). In this case, in addition to Van Gogh’s pentimenti is his habit of painting over previous works. All of this adds to a type of “fingerprint” that art appraisers use to identify works of art from forgeries… Cool.
Today, we have to use “pentimenti” in a sentence (see rules here). Here are two examples to help you along:
Serious: I wonder how Van Gogh’s pentimenti differs from that of Rembrandt. Maybe I should ask the Musee du Louvre’s curator for some insight.
See you in the blogosphere,
Pascal Tyrrell
MiWord of the Day Is… X-Ray!
Yup! Want some of that. Not only is Superman cool but he has x-ray vision. Unbelievable. Or is it? Radiologists have the same x-ray vision but without the Spandex suit – or at least they don’t wear it to work that I am aware of.
The word of the day is x-ray. You have already successfully used “Roentgen” in casual conversation last week (don’t know what I am talking about? See Mi Word of the Day Is… Roentgen!) and today I will talk a little about what Roentgen was first in measuring and describing – x-rays.
Let’s say you are in your lab and you are working with passing electrical discharges through vacuum tubes – a typical Saturday afternoon activity with friends. As chance would have it your little sister’s barium salts paintings happen to be drying near-by and you notice a faint glow emanating from them every time you run your experiments. No matter how much you try to block any light coming from your vacuum tubes the glow persists. What? That’s odd. How’s that happening? Well my friend, you have just crossed over into the Twilight Zone (awesome old tv series) and discovered a form of electromagnetic radiation.
Visible light is but a very small part of the electromagnetic spectrum. Moving from visible light to longer wavelengths and lower frequencies we find infrared (keeps food warm at restaurants), microwaves (to warm your pizza pop) and radio (not the one streamed through the internet!).
Now if you move in the opposite direction from visible light you find shorter wavelengths with higher frequencies starting with ultraviolet (what helps you get that summer tan), x-rays (word of the day), and finally gamma rays (topic for another day!). So x-rays are about the size of atoms and radio waves the size of buildings. Crazy. I think what is surprising is that with the naked eye we “see” so little and yet so much (philosophy anyone?).
So, x-rays are short wavelength, high frequency, high energy electromagnetic radiation that is able to penetrate some substances more easily than others. For example, they penetrate flesh more easily than bone, and bone more easily than lead. Thus they make it possible to see bones within flesh and a bullet embedded in bone. The ability of X rays to penetrate depends on their wavelength and on the density and thickness of the substance being scanned.
2- You have to use the word in a sentence by the end of the day. No need to use it in the correct context – actually out of context is more fun and elicits a more entertaining response!
Serious: Hey Frank, did you know the radiation you received during your chest x-ray last week was actually “soft” x-rays? Ones with shorter wavelengths and more penetrating power are used for scanning archaeological artifacts.
Less serious: Frank! Dude, I got them! My x-ray specs just came in the mail. Let’s go the beach…
See you in the blogosphere,
Pascal Tyrrell
MiWord of the Day Is… Roentgen!
Welcome to the first Medical imaging Word of the Day! Here is how it works:
1- I introduce and discuss a word.
2- You have to use the word in a sentence by the end of the day. No need to use it in the correct context – actually out of context is more fun and elicits a more entertaining response!
OK, here we go. The word of the day is Roentgen – typically pronounced “Rent-gun”.
Wilhelm Roentgen was a physicist from northern Germany who in 1895 was the first to detect the now famous x-ray. Interestingly, he was not the first to produce them. The x-ray is part of the electromagnetic spectrum that contains shorter wavelengths (0.01 to 10 nm) than visible light (390-700 nm). We will talk about this in another post as today it is about Roentgen.
- Following his discovery the “Roentgen unit” was described and used to measure x-ray exposure (one R is 2.58×10−4 C/kg). About 500 R over 5 hours is considered a lethal dose for humans.
- Roentgen was the first scientist to receive the Nobel prize in physics in 1901. He refused to patent his discovery and gave the entire prize money to his university. Wow, what a guy!
- He died of colon cancer in 1923.