Communicating Chemistry (2020w209)

Re-wiring Your Brain For Sugar Craving

Posted on March 2, 2020 by Pricia Ouyang | Leave a comment

Have you ever wondered why we have desires for sweet food but not bitter food? Dr. Li Wang and other scientists at Columbia University have discovered that mammalian brains for tasting can be re-patterned or erased by performing a series of experiments on mice. This study has significance for future studies in eating disorders and weight management.

The taste sensory system

Mammalians have a developed sensory system for identifying tastes and associating tastes with mechanisms of reward and aversion. This sensory system has two main parts: the tongue and the brain. There are many sensory neurons in our tongues. These sensory neurons, the detectors of the five basic tastes (sweet, sour, salty, bitter and umami), signal our brains and turn on the amygdala of the brains responsible for identifying and interpreting tastes. Dr. Li Wang and her team have confirmed that neurons in the sweet-responsive cortex project to a different area compared to those in the bitter-responsive cortex. The strong segregation of neuron projection transmits desirable, or aversive taste signals, as shown in Figures 1 and 2. Therefore, we cannot stop eating sweets since our amygdala associate sweets with appetitive, desirable signals.

Figure 1. b and c show the active bitter taste cortex and active sweet taste cortex respectively. Source: “Nature Journal”

Figure 2. Licks per second (Licks rate) of mice upon photostimulation of the sweet and bitter cortexes. Adapted from “Nature Journal“

Rewiring the brain on taste

Dr. Wang and her team rewound the brain of mice on taste by using a drug to silence the neurons in the sweet-responsive cortex and the bitter-responsive cortex, respectively. The team used licks per second to quantify and verify the appetitive and aversive responses of the mice upon photo-stimulating the sweet and bitter cortexes independently. The team found out that by silencing the neurons in the sweet cortex, the lick rate decreased, according to Figure3. This showed that the mice could not recognize sweet when the neurons were silenced by the drug. This confirmed that the taste specific neurons are essential to recognize tastes.

Figure 3 also showed another interesting phenomenon that the team made the animals think they were tasting sweet, even when the animal was drinking water. In Figure3, without the presence of the sweet neuron silencer, the lick rate of the mice with their sweet cortex stimulated was two times higher compared to the mice without the stimulation. The increase in the lick rate in Figure 3. showed that neurons in the amygdala control an animal’s sensory perception of taste.

Figure 3. Photostimulated sweet cortex in the presence or absence of sweet neuron inhibitor. Adapted from “Nature Journal”

The finding that animals’ brains can be manipulated and rewound to change the perceptions of taste has implications in future studies in weight management and eating disorders. By using small drugs to target these taste-specific neurons, we may say no for eating more and more sweets.

Reference

Li Wang. The coding of valence and identity in the mammalian taste system. Nature Journal, 2018; 558, 127-131. DOI: https://www.nature.com/articles/s41586-018-0165-4

Pricia

2020-03-02

Don’t Let Stress Get The Best of You

Posted on March 1, 2020 by Athena Wang | Leave a comment

You may have heard of the saying, “diamonds are made under pressure”, especially from people working last-minute to meet deadlines. However, a study found that the stress accompanying our seemingly never-ending tasks actually decreases our ability to produce high-quality work, or to perform well on exams.

The study showed that upon chronic stress, neurons shrink in the hippocampus, which is the region in the brain that controls our memory; this equates to a weaker memory. Furthermore, neurons end up growing in the amygdala, which is the region in the brain that reinforces our fears; this translates to an increase in anxiety levels.

Figure 1. Chronic stress promotes the growth of neurons in the amygdala (a), and leads to the shrinkage of neurons in the hippocampus (b). Created by Athena Wang. Adapted from Davidson and McEwen (2012).

Therefore, instead of studying a week before exams when stress levels are the highest, you should space out your studying throughout the semester to retain as much information as possible while also being more calm.

ACUTE VS. CHRONIC STRESS

A bit of stress can be good for us; acute stress triggers our fight-or-flight response, and helps us overcome short-term stressors. However, chronic stress weakens our immune system, and leads to even more troubles, such as mental health and cardiovascular problems. Therefore, stress should be dealt with before it escalates.

WAYS TO RELIEVE STRESS

Good time-management skills are important, so that you don’t end up with a plethora of assignments due at the same time. Designate and follow the allotted times for your tasks, and hopefully having a better control over your time will decrease stress.

Another way is to practice mindfulness. This type of meditation makes you embrace your current situation and not dwell on unnecessary worries, which then allows you to feel less stressed. Lastly, incorporate enjoyable activities in your schedule to improve your mood and help you relax.

The next time you’re feeling stressed out, don’t let it get the best of you. Take a deep breath, and remember that you’ve got this!

Any additional tips? I would love to hear your thoughts in the comments below.

-Athena Wang

Enhancing Safety Gloves

Posted on March 1, 2020 by wilson wong | 1 comment

Safety gloves do not protect you from every chemical or dangerous substance. The glove deteriorates and makes it easier for chemicals to penetrate through and onto the skin. One way to tackle this problem is by implementing a self-healing material, which can be used for rubber gloves.

Researchers at the Central Institute for Labour Protection in Poland tested polyamide, cotton–polyamide, and cotton fabrics, onto methyl vinyl silicone rubber containing inorganic silsesquioxane, which are used for rubber gloves. Its resistance to chemical substances, abrasions, and punctures were analyzed. Using SEM, the surface is observed for any damages or self-healing behaviour for each rubber material containing each type of fabric.

A cross-section of a rubber material with textile reinforcements (Source: Irzmańska)

A test to determine the resistance of chemical substance with methyl vinyl silicone rubber with silsesquioxanes, and one coated with cotton was carried by using 2-propanol. This studied the breakthrough time of the 2-propanol through the 2 different materials at various conditioning times. The idea is to simulate the effectiveness of the self-healing mechanism.

Permeation times of 2-propanol into 2 different materials (Adapted: Irzmańska)

The data shows an increase in permeation time when coated with cotton, and when conditioned at 70 degrees Celsius for 24, 48, 72 hours. This means coating the material with textile reinforcements increases the resistance of chemical substances from penetrating. A similar trend was obtained when testing different textile compositions through puncture and abrasion tests.

The result concludes the effectiveness of the textile reinforcement in the self-healing process, qualitatively and quantitatively. This study brought improvements to lessen the stress chemists have on the quality of their own safety gloves. Safety gloves should never be a safety concern.

-Wilson Wong

1 Comment

Posted in Analytical Chemistry, Chemistry News

Tagged Safety Gloves, SEM

Where Fluke meets Fortune: How Chance Lead to Discovering Novel Green Chemistry Reactions

Posted on February 29, 2020 by mark rubinchik | Leave a comment

Dr. Petri Turhanen from the University of Eastern Finland discovered that Dowex, a cation exchange resin, opens up an untapped area of green chemistry – the scientific initiative to find chemical reactions that produce the least waste. The best part? It wasn’t on purpose.

While working on an organic synthesis project in 2015, Turhanen noticed that the cation exchange resin he was using, Dowex, produced an unintended byproduct in the presence of sodium iodide (NaI), an iodide (I^–) source. Further analysis unveiled that the byproduct was the result of an iodide addition reaction. This is a reaction where a double bond between two carbon atoms is converted into a single bond with a new atom on each carbon, one hydrogen and one iodine.

The novel and green iodide addition reaction discovered by Dr. Petri Turhanen

The source of this unique reactivity comes from the polymer known as Dowex. Dowex is a solid resin made of polystyrene sulfonate. Its main use is as a cation exchange resin, a type of solid that is able to exchange cations, such as H⁺, for other cations, such as Na⁺ or K⁺.

Why is this reaction significant? Iodinated molecules serve multiple purposes. They are often intermediate molecules in organic synthesis, acting as a precursor to building up larger, more complex organic molecules such as pharmaceuticals. Furthermore, radioactive iodine isotopes attached to organic molecules are used as tags in medical imaging.

The industrial processes used to iodinate compounds require toxic starting materials, harmful solvents and high temperatures. These include hazardous, or even carcinogenic, compounds such as iodine, hydrogen peroxide, trimethylsulfonium iodate and iodine monochloride and heavy metals catalysts. To contract, Dowex has low toxicity and can be reused after the reaction is complete.

Comparison of iodide addition reactions

Since the first experiment in 2015, Turhanen has expanded the library of reactions possible in the presence of Dowex, such as esterifications and the conversion ethylene to a di-iodide species. Continued organic synthesis initiatives such as Turhanen’s will pave the way for a greener future of science.

-Mark Rubinchik

Stress and Grey Hair: An Answer to a Biological Mystery

Posted on February 29, 2020 by Kenny Lin | 2 comments

Everyone has heard that too much stress will cause grey hair. This is easily seen in former president of the United States, Barack Obama, whose hair could not escape the stress of the Oval Office! But what exactly links grey hair and stress? This year, researchers at Harvard University found that the nervous system eliminates pigment-regenerating stem cells responsible for coloring our hair!

Barack Obama’s hair color at the start of his presidency versus seven years after. Credits: DailyMail.com

the root of the problem

When you are stressed, your body responds in three distinct ways: the activation of your immune system, the activation of your sympathetic nervous system (SNS), and the release of cortisol, an energy-stimulating hormone. All these responses put your body into a “fight or flight” mode; increasing heart rate and blood pressure. The challenge for Zhang’s team was to sort through these three responses and determine which caused grey hair.

Zhang’s team tackled this problem by performing a series of experiments on black-furred mice. They first tested if immune system activation was the cause by seeing if the fur greyed under stress, even when the immune system was deactivated. They indeed found that stressed immune-deficient mice still greyed, indicating that stress causes greying, independent of an immune response.

They also ran similar experiments using mice mutated to not respond to cortisol or noradrenaline, a molecule involved in SNS activation. The idea being that if a response was involved, stress should not cause the fur to grey if it was removed. In mice lacking response to cortisol, the fur still greyed; however, in mice lacking the response to noradrenaline, their fur remained black! This indicated that the SNS was the main driver in hair greying.

Figure 1. The results of the experiments described above are shown. Note that mice unable to respond to SNS activation do not grey under stress. “Control” refers to unmutated mice. Also note that a different type of control (non-stressed vs stressed) was ran in the immune-deficient case. (Sample size = 6 for each condition, standard error bars). Credits: Adapted from Zhang et al.’s data.

Zooming in further…

With the culprit in hand, Zhang’s team didn’t just stop there! Through further experimentation, they illustrated that the SNS over-stimulates MeSC, the stem cells involved with hair pigmentation. During hair growth, these MeSC cells transform into pigment-producing cells and color the hair. Under stress, the SNS causes these MeSC cells to transform at an abnormally high rate, quickly depleting these cells and leading to grey hair.

The reason behind this link?

In truth, the reason why this MeSC and SNS interaction exists is unclear. Zhang’s team suggests an evolutionary perspective. Since octopuses, a distant relative to mice and humans, can modify pigmentation of their skin using the SNS, they hypothesize that this interaction was simply conserved. Whatever the reasons may be, this just further shows that the mystery has yet to be completely solved!

-Kenny Lin

2 Comments

Posted in Biological Chemistry, Popular Science

Tagged Grey hair, Nervous system, Stress

Antibiotics found to kill bacteria in a new way!

Posted on February 25, 2020 by xinyu gu | 4 comments

Fig1.Antibiotics source

Antibiotic is the most powerful “weapon” to fight against bacterial infections. However, according to the World Health Organization, there are more than 700000 people die every year due to antibiotic resistance. On Feb 13th, 2020, Research team from the David Braley center for Antibiotic Discovery, University of McMaster posted an article on nature. Newly found corbomycin and complestatin would kill bacteria in a brand-new way. The discovery of these new groups of antibiotics would be the clinical candidate in the fight against antimicrobial resistance.

Fig2,Antibiotic resistance strategies in bacteria. source:Courtesy of E. Gullberg.

Antibiotics are the revolution of the pharmaceutical study in the 20th century. They are the most important type of antibacterial agent which either kills or inhibit the growth of bacterial cell walls. Alexander Fleming discovered modern antibiotic medicine – penicillin in 1928, which saved thousands of people’s life.

What does old antibiotics also bring you?

The enormous benefits of antibiotics also lead to new problems such as over-usage and resistance. Bacteria soon formed resistance toward these antibiotics and caused the ineffectiveness of the medicine. The resistance of antibiotics had become a new-rise problem. The World Health Organization announced: “serious threat is no longer a prediction for the future, it is happening right now in every region of the world and has the potential to affect anyone.”

Fig2.image of corbomycin. source

The newly found corbomycin and complestatin have brand new way to attack bacteria. It is discovered from a glycopeptide family, and the new approach appears no significant resistance toward bacteria. “Antibiotics like penicillin kill bacteria by preventing the building of the wall, but the antibiotics that we found actually work by doing the opposite – they prevent the wall form being broken down. This is critical for cell to divide.” Said Beth Culp, a PhD candidate in biochemistry at McMaster.

Why do we know about these?

“We hypothesized that if the genes that made these antibiotics were different, maybe the way they killed the bacteria was also different”, Culp explained. The “unique approach” to kill bacteria is a new mechanism that is worthy of studying. Scientists might be able to find the new family of antibiotics which have a completely different way to attack bacteria. These new antibiotics will be the revolution of modern biochemistry which will be powerful to fight against antibiotic-resistant.

Scientists believed that the observation of corbomycin and complestatin would open the “new door” in the field of antibiotics. People will be able to investigate more antiobiotics to fight against resistance in the glycopeptide family. This study will eventually benefit thousands of people suffering in antibiotic-resistant and give them hope to survive!

–Vicky Gu

4 Comments

Posted in Biological Chemistry, Chemistry News, Popular Science

Tagged antibiotics, antibiotics resistance, corbomycin

Polyurethane – a chemical in your mattress

Posted on February 24, 2020 by Young-jung cho | 2 comments

We are living in “the polymeric world”. What does it mean by the polymeric world? Look around you! We cannot keep away from the materials made up of polymers. Probably, the most common polymer exposed to our body would be a polyurethane, if you sleep on some sort of a comfortable mattress.

The use of polyurethanes

How does a mattress relate to a polyurethane? The polyurethane is a cushioning material to produce a flexible and rigid foam. More than 50 % of polyurethanes are consumed to make the foams (Figure 1). In addition to the function of recovering an original shape, the rigidity in the range between a flexible rubber and a hard thermosetting plastic makes polyurethanes the best material for mattresses.

Figure 1. Uses of polyurethanes for various materials. Mainly, polyurethanes are used to produce foam materials. This figure is modified from the open source

The carbamate group and the backbone of polyurethanes

How could polyurethanes have rigid and flexible properties? The chemical structure of a polyurethane would explain its properties. The polyurethane is a block polymer produced from two monomers, a polyol and a diisocyanate. The reaction between hydroxyl and cyanate groups gives a rise to repeating carbamate groups in a long chain (Figure 2; left). The polar carbamate group can have intermolecular hydrogen bonding, resulting in the decrease of free volumes within a polymer system (Figure 2; right, Figure 3). Therefore, polyurethanes can have the rigid property associated with the carbamate group.

Figure 2. A chemical reaction of a diol and a diisocyanate to form a polyurethane (left). Intermolecular H-bonding of polyurethane chains (right).

Figure 3. A flexible polymer system due to a large free volume (left). A rigid polymer system due to a small free volume (right). Polyurethanes would resemble the small free volume system due to intermolecular hydrogen bonding.

The backbones of polyol and diisocyanate are also an important factor to control the flexibility of polyurethanes. The flexibility of a long hydrocarbon chain, which both or either the monomers can have, would be introduced intrinsically to the polymers. This implies that polyurethanes can be variously derivatized, switching the backbone of diols and diisocyanates.

-Young Cho

2 Comments

Posted in Organic Chemistry

Tagged polymer, polyurethane

A greener approach to organic synthesis with reduced organic waste

Posted on February 24, 2020 by aron engelhard | 3 comments

It may sound counterintuitive, but it is in fact a reality. Organic solvent waste is one of the main contributors to pollution generated by the pharmaceutical industry worldwide. These substances are widely used in the preparation of drugs and other vital compounds, and recycling them represents a great challenge for many other industries. Fortunately, a team of researchers from the University of California Santa Barbara, has figured out a way to dramatically reduce the use of organic solvents in widely used synthetic procedures using micellar nano-reactors.

Formation of a Micelle Nano-reactor in aqueous medium. Adapted from https://www.kruss-scientific.com.

It is now possible to perform synthetic procedures in an inorganic solvent, such as water. The key aspect of this technology is the use of functionalized Vitamin E derivatives as nano-catalytic centres that enable organic molecules to react in an inorganic medium. Vitamin E is a lipid-soluble compound, when functionalized, it is able to form micelles in an aqueous environment that dissolve organic compounds as well as other reactants. Reactions take place inside each of these micelles due to their lipophilic character, enabling the entire process to be carried out in water.

Structure of Micellar nano-reactor. Adapted from ACS.

So far, this technique has been used in a wide variety of reactions which include but is not limited to: Cross-couplings, olefin metatheses, trifluoromethylations and aminations, with high yields, little waste and reduced costs. In many industries, waste is measured in E factors. An E factor is defined as the quotient between the amount of produced waste in kg, divided by the amount of desired product obtained by the process.

E Factor comparison between pharmaceutical methods and researchers work for cross coupling reactions. Adapted from Green Chemistry

The nano-reactor technology has demonstrated a decrease in E factors for as much as 98%, meaning that this method could drastically change the effect of big corporations in our environment.

-Aron Engelhard

3 Comments

Posted in Organic Chemistry

Dogs resemble their owners, finds study

Posted on February 24, 2020 by vanessa jansz | 5 comments

Dog and his owner. Photo by Thomas Hawk on Flickr

Have you ever heard the adage “Dogs resemble their owners?”

A psychological study by Michael Roy and Nicholas Christenfeld published in 2004 by Psychology Science found that our canine companions actually look like us!

THE RESULTS

The study concluded that pure-bred dogs can be correctly identified to their humans significantly more than mixed breed dogs.

Figure 2 shows the results of the study that focused on pure-bred dogs. It shows that strangers (the ‘judges’) were able to identify the correct dog to it’s owner 16 out of 25 times (64%). Also, it showed the judges were able to decide between the dogs and no ties were shown.

Figure 2: Judges results for pure-bred dogs (n=2). Chart created by Chantell Jansz, data from “Do Dogs Resemble Their Owners”

Figure 3 shows the results of the study that focused on mixed-breed dogs. The judges were only able to identify the correct dogs to it’s owner 7 out of 20 times (35%) . Additionally, the judges were more indecisive in their decision as there is a greater proportion of ties for mixed dogs.

Figure 3: Judges results for mixed breed dogs (n=20) Chart created by Chantell Jansz, data from “Do Dogs Resemble Their Owners”

The mechanism as to where the resemblance comes from is still uncertain. However, Dr. Christenfeld suggests,“It’s not people coming to look like their dogs when they live together. Instead it’s that people pick a dog that resembles them … but with a mutt you don’t know what it’s going to look like [when it grows up].”

METHOD

The researchers took pictures of 45 dogs (25 pure-bred, 20 mixed) and their owners from 3 different dog parks. The pictures were taken with care, to ensure the judges could not match the dogs to their owners based on the background of the photos.

The judges (a group of 28 unknowing undergraduates) were shown 3 pictures at a time. The 3 pictures were a dog, the dog’s owner, and another dog from the same park. The judges were asked to pick which dog out of the two, belonged to the owner pictured in front of them. This process was repeated for all 45 dog owners to produce the results (shown above).

Clearly, the results show a trend in the ability of a random individual to identify a dog to it’s owner. However, the study was only done on 45 dogs, limiting the results.

OTHER EVIDENCE OF RESEMBLANCE?

Our furry friends can resemble us more than just physically, found Psychologists at Michigan State University. The paper published in the Journal of Research in Personality in 2019 studied 1681 dogs belonging to 50 breeds, aged between a few months and 15 years.

The study found that dogs’ personalities match their owners. For example, owners high in agreeableness, conscientiousness, and open-mindedness rated their dogs as less fearful, more excitable, and less aggressive. While, owners high in negative emotions rated their dogs as more fearful and excitable, and less responsive to training.

WHAT DO THESE STUDIES MEAN?

Chances are, if you have a dog it probably resembles you physically if not, emotionally!

– Chantell Jansz

5 Comments

Posted in Popular Science

Tagged dog, dogs, humans, psychological research, psychology, resemblance

Strategic Dating: The 37% Rule

Posted on February 24, 2020 by yuchen ding | 3 comments

Dating and settle down are big problems for a lot of people, especially for many scientists, who spend their entire life in labs. For rich people, dating can be easily solved by economics. However, for the poor, dating is a metaphysics problem. How can we dating and settle down efficiently? It turns out that there are many mathematical rules that tell you how long you ought to search, and when you should stop searching and settle down.

Secretary problem

The secretary problem is a problem that demonstrates a scenario involving optimal stopping theory. In the secretary problem, an administrator is interviewing n applicants in turn to help the company to hire a best secretary. A decision must be made immediately after each interview, and once the interviewee has been rejected, it cannot be recalled. The question is about the optimal strategy to maximize the probability of selecting the best applicant.

Similarly, for dating and marriage, you must decide whether to settle down with your current boyfriend or girlfriend at some time points. This can be solved by the secretary problem. For example, assuming you have 3 different boyfriends in your lifetime, and you need to choose one to marry him. The best strategy for you is to break up with your first boyfriend regardless of how excellent he is, try the second one. If the second one is better than the first one, marry him, or try the third one. In this case, you have ½ probability to choose the best guy, which is more probable than choosing randomly.

Demonstration on the scenario talked above.

The 37% Rule

However, in the real life. The sample size is unpredictable, and largely depends on a lot of things. How large the sample size should be and how many boyfriends should you “try” before you make the decision?

First, we can make an assumption: There are n boys chasing you, you try first k (k<n) boys but reject all of them. From the k+1 boy, settling down if he is better than the previous ones. For example, when n=4, there’re 4 possible k values: k=0, 1, 2, 3. By listing all possible cases, we got when k=1, P₍₁₎=11/24, which is the best strategy for you to choose the “Mr. Right”.

Possible cases for Sample size=4. (Source: DataGenentics)

More generally, for a very large sample size, the probability can be calculated from Riemann integral and its derivative:Which means you should settle down immediately when you meet the “best boy” after you try first 36.8% guys in your life.

Comparing with choosing randomly, it is obvious that when the sample size is larger than 2, using The 37% Rule is much more possible to settle down with your “Mr. Right”.

A comparison of choosing randomly and choosing by the 37% rule. (Data Source: DataGenentics)

However, in the real world, you never know how large the sample size is. Although we can approximate a n value by combining many factors like economic status, educations, personal experiences, family background, face score and etc. Life is not a game, so settle down in a relationship with your true love when you think he or she is your best choice.