My thoughts on the Google Pixel 2

As you may or may not have noticed, I’ve not written anything in a while. After starting a new job a few months ago I’ve been exceptionally tired and lacking motivation.  I got to that point in my mobile phone contract when I was bored of my phone and it wasn’t going to cost any more to upgrade – so thought writing about my new Google Pixel 2 would be a good reintroduction to my blog. Bear in mind most of the science behind mobile phones is physics, which is far from my specialty, so any science mentioned will be basic! But I’ll share my thoughts on the phone, then a little about smartphone science.

I managed to get my phone when it was released on Thursday 19th, alongside the free Google Home Mini that came with it (nice little extra!). To be honest, I couldn’t unbox it straight away like I really wanted – I was far too hungry after work so I had to contain my excitement for a bit longer…

It was an easy set up with helpful advice on transferring across from my iPhone. I was desperate to get playing with it: first impressions were tainted by the criticism I’ve heard about the relatively chunky bezels top and bottom, but it didn’t bother me – it looked clean and simple, it meant there were no extraneous lines or funny-looking joins anywhere. The latest OS Oreo seemed built for the Pixel and it was a welcome relief not to find all the usual bloatware from the manufacturer you would otherwise find.

The first feature I liked was the subtle motion wallpaper: although the display isn’t as high resolution at its XL sibling, it’s very impressive. The colours do look great on it, I imagine the OLED screen helps with that. There are basic components to every mobile phone: circuit board, screen, battery, microphone, speaker, antenna, those sort of things. And most of the smartphones this year have pretty similar specs, but the software is usually the thing that differentiates them.

 

Screenshot_20171021-125437
The home screen with the clean layout: At a Glance on top and search bar at the bottle.  With this wallpaper, the waves gently crash against the sand.

 

Noticeably impressive, somewhat surprisingly, is the fingerprint scanner. It’s very quick and is convenient for me at least. The most recent fingerprint scanners are capacitive – measuring the difference and pattern of electrical charge when the ridges make contact.  There are no buttons involved in unlocking the phone or even to see notifications, it’s all pretty speedy and simple.

I’ve not tested the Always On display’s effect on battery life, but it is useful, giving the time and icons of notifications you may have.  A slightly creepy feature is Now Playing, where your phone just listens out for a series of offline musical patterns to show you what song’s on in the background – handy, but still creepy.

Now, the somewhat flagship feature of the phone – the camera, with the (for now) highest DxOMark rating of 98. Google hasn’t followed the trend of adding a second lens to the rear but have managed to quite effectively add Bokeh portrait mode via software, which also works with selfies. The image stabilisation is very effective – using optical and digital image stabilisation to get rid of all the jitters. I like it anyway! It’s 12 megapixel and capable of 4K video recording.  With Google’s unlimited cloud storage it’s definitely a good perk.  Having had a few days use of the camera, I’m pretty impressed but will need a while with different conditions to really find out its limits.

Having a Chromecast and now the free Google Home Mini too has meant it’s really easy to cast music and videos over to either. The Google Assistant is actually fairly useful – on the Pixel 2 and Home Mini, with the addition of the Active Edge “squeezy sides” on the phone to launch the assistant (and silence calls) is just a neat little extra. I mean it would’ve been nicer to customise the Active Edge to launch something of your preference but that’s just a software issue for now.

It’s hard to tell how good the battery will be, I’ve been using it a lot so not really typical use. At 2700mAh it’s not astonishing but Google’s advertised it to be quick charging, so we’ll see…

Overall I’ve enjoyed the Pixel 2 so far, it sits nicely in the hand and pocket and is quick and effective and doing what I’ve wanted.

Some basic properties of smartphones are quite interesting: some highly complex and some rather simple. The elements used can be relatively rare, as you can see below, one of the reasons they can be so expensive.

The-Chemical-Elements-of-a-Smartphone-v2

Something rather simple, albeit probably proprietary, is the popular feature of being waterproof. There’s usually a lot of glue around the edges and o-rings at the ports for mechanical protection, and a special small mesh for speakers etc, letting air in. They’re often coated in Gore-Tex.

Applying smartphone technology into something helpful to society like medicine has always been of personal interest; as you may or may not have read before, I’m diabetic, advances like the trials into reading blood glucose levels with a smartphone sound pretty cool. The ease of doing such mundane things several times a day is boring enough, also meaning carting around the equipment to actually test. Advances like this are always welcome! There’s currently a system that uses NFC in android phones to get glucose readings from a small device that sits on the arm – but it lasts 10 days and costs about £60 a pop.

Hopefully, that’s a good enough insight, for now.  Let me know your thoughts if you’re due for an upgrade soon!

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Our favourite poison

After recently writing a few posts seemingly promoting alcohol, I thought it apt to bring some balance with a brief description of what this particular alcohol, ethanol, does to the body and more worryingly, the mind with any benefits it may have.

We’re not that special in drinking alcohol for pleasure, it’s been about for a while. Eating fermented fruits was probably the beginning.  Then actually saving lives when water wasn’t drinkable or available: beers, gins, Mead, and wines.

You always remember having too much of your tipple when you have a crippling hangover. Most of this is just dehydration; you’ll remember going to the toilet a lot the night before – alcohol stops a hormone being produced in a little gland called the pituitary gland in the brain (vasopressin or antidiuretic hormone) which would normally tell the kidneys to keep some water.

The reason you’re still drunk for quite a while after you stop drinking, and why that hangover keeps hurting is because the stuff that breaks down virtually everything you eat and drink, transforming it into something useful, the magical enzymes, can only work so fast! If you did any biology in school or even chemistry, these biological catalysts speed up chemical reactions, and they’re quick, but when you’ve overwhelmed the poor guys with half a dozen Jaegerbombs half way through the night, it’ll take a while. Everyone’s different of course, which is why everyone is different with how much they can process alcohol; if you read my last post, you’ll know about DNA. Well, this is one factor in how much of these enzymes are produced, and at least half a dozen other factors controlling how much of this little ethanol molecule gets into your bloodstream.

It doesn’t take long for the little bugger to get to work – if you’ve got an empty stomach it’ll pass through the stomach lining meaning it’ll work its way to the brain quicker. This is where most of the ethanol’s effects take place. It’ll work its way across the brain, like I’ve described before, as it inhibits normal functions like behavior, inhibiting risks like social anxiety!

We seem to like to drink, linked to the good feeling we get from it at a basic chemical level – a little chemical in the brain called dopamine. It’s released by nerve cells so it’s called a neurotransmitter and it reinforces behaviors that cause it to be released. It’s also a part of addiction including to narcotics, explaining why people can so easily become addicted to alcohol. There’s that warming feeling we seem to get with alcohol: it makes the blood vessels in the skin come to the surface, so you’ll be nice and cozy on the outside. The problem is, this is the body’s mechanism for cooling down; hypothermia is an unfortunately common occurrence having had a lot of alcohol.

This infographic details nicely the effects of alcohol: physical, psychological and almost econographical.

There are the commonly publicized advantages of drinking some forms of alcohol. A generic benefit of moderate alcohol intake is a reduced risk of dying from heart disease, but I’m pretty sure not smoking and getting regular exercise would be a better way to achieve this. Red wine is often quoted as being healthy, which with high levels of polyphenols is sort of true, but again in moderation. These wonderful class of molecules are found in highest concentrations in red wine compared to other alcoholic drinks. This comprehensive article describes why a glass of red wine with your dinner should be encouraged!

Historically gin was a ‘healthy’ drink, much like beers were, being safer than drinking water in a lot of places, not to mention the tonic’s antimalarial properties undoubtedly saving many people. The defining ingredient of gin, the juniper berry, has loads of health benefits, like antioxidant and antimicrobial, which may help reduce effects of aging (e.g. wrinkles) and infections, respectively. However, I’m not sure there are necessarily any studies to show whether the concentrations required to have an effect would be completely outweighed by the drawbacks of alcohol consumption! Just have a regular portion of blueberries – they’re a sure-fire way to get your fix of health benefits. If you are choosing to have alcohol, gin is certainly a good drink to have if, like me, you’re diabetic: it’s low in both calories and sugar. Read all about gin here.

I don’t think I’d be outlandish to suggest to drink alcohol in moderation – as part of a healthy diet, seeking medical advice if on medication etcetera, etcetera. Get some good advice here. So enjoy a little alcohol, and perhaps if you’re drinking red wine or gin, you’ll live a bit longer. Like anything in excess, alcohol isn’t healthy, so be responsible!

What are we made of? The unit of life

Last week I was chatting about the basic constituents of the body – quite literally what we’re made of, the elements and the working up of all the systems that join together. This week is a look at the controller of all that stuff – the thing that makes it all happen from our single fused-cell origins to the fully-formed trillions of cells we are today. Our deoxyribonucleic acid (DNA) sits protected in the nucleus of our cells and controls everything we are and everything the cell is and does. I’m sure describing DNA has been done a million times over, so I just want to make it a bit more understandable and tell you how amazing it actually is!

Below you’ll see what DNA actually looks like. It’s only when cells are ready to divide that it’s all coiled up tight into the chromosomes we’re used to seeing – it’s been twisted so much it’s called supercoiled.

dna structure 1

It’s made of things called nucleic acids, attached to a backbone of sugars and phosphates. The nucleic acids are the letters of the genetic code, called Adenine, Thymine, Cytosine and Guanine. In one strand of DNA, there are all these letters and they match the other strand since A only binds with T and C only binds to G, the bits just chemically match up and they seem to like each other!  See the image below, it shows you the chemistry of it all.

Chemical-structure-of-DNA

So great, there’s a big coiled bunch of chemicals held together in strands by this backbone. Crick and Watson theorized this shape it forms – the double helix. Now the fun comes with what all these letters do. When a bunch of letters together do something specific it’s called a gene; it “codes” for proteins. Basically, every three letters correspond to a specific building block – an amino acid. This means joining amino acids together in this specific order makes unique proteins. These fold up in unique ways too to eventually form proteins. It’s proteins that carry messages, give structure, virtually everything that makes cells and the body functional. Humans have about 20,000 genes that all encode proteins, which is a lot, but not really considering how many different functions cells have with all their unique components.

Cells can’t function properly if they don’t have DNA to make and control all the bits to keep it going. This is why there’s a security system in place to make sure that when it comes to making copies of itself, it’s only done if DNA is intact, without any changes being made to any of the letters – these are called mutations. So when the cycle comes round and it’s cell multiplying time, the DNA all condenses into the chromosomes we’re used to seeing. If there are any mutations it stops and will try repair it; if it can’t, it goes through a programmed cell death (apoptosis). If maverick cells ignore this, cells keep dividing until masses form – known as tumors, then certain criteria define it as cancerous.

So it’s pretty amazing stuff this DNA. It’s also true that we share most of it with our friends the chimpanzee. But there are a lot of “conserved sequences” which is why animal models are so useful in experimentation – if they make the same proteins as us, we can see the effects of its mutation or absence by following it around and seeing where it works and what it does. By tagging the proteins the sequence makes with something radioactive or fluorescent it can be tracked to see what’s going on. It’s been revolutionary in understanding countless mutations that can cause diseases and disorders.

Have a look below for the background of genetics and a summary of what DNA is and does. Meanwhile, since it’s summertime, go get some strawberries… and keep a few to extract some DNA for yourself! All you need is some salt, washing up liquid and ice cold rubbing alcohol/vodka. Look here for the instructions!

https://visual.ly/track.php?q=https://visual.ly/community/infographic/science/history-genetics&slug=communityinfographicsciencehistory-genetics From Visually.

What are we made of? The Basics

I’m not very philosophical, so strictly scientifically – what are we?  It’s a complex thing the body, tiny but important parts all together making a pretty robust organism. There are a few different ways to look at this, it depends on how microscopic you want to go: systems, organs, tissues, cells, molecules, atoms.  You could go smaller but it’s too small for me – quantum mechanics governs that stuff.

You could get roughly 160 billion helium atoms side-by-side in a centimeter but there’s a relatively huge gap between the middle (nucleus) and the electrons whizzing round the outside of the atom.   If the Earth was an atom, the nucleus would be a football stadium. All the space adds up, so we are mostly empty space, but so is everything else!  The atoms that make us are a little bigger than helium, but not hugely…

periodic table

Oxygen ~65%     Part of water (H2O) that’s in every cell in the main fluid of the body.

Carbon ~18.5%     It’s in every carbohydrate, protein, fat, all the organic chemicals in the body.

Hydrogen ~9.5%     The other part of water, and in your organic chemicals too, not very big or heavy, but very important.

Nitrogen ~3.3%     It’s in all your proteins, the amino acids that make them have it and the nucleic acids your DNA is made of.

Calcium ~1.5%     Bones and teeth: we all know how important they are! Also used in signaling to make muscles contract.

Phosphorous ~1%     The major player in energy is something called ATP, the P being phosphorus, so very important! It’s in bones too.

There’s a lot more, like sodium, potassium, and magnesium that help electrical signals in the body, that’s those “electrolytes” you may have seen in sports drinks. There’s probably hundreds of elements inside you, including arsenic and uranium! But the top four make up over 95% of your body weight, so there aren’t much of the others but we need them!

Thinking bigger, we get cells. Cells are amazing: they’re the functional units that make us, the building blocks. We have trillions of them and they’re all specialized.

Cells of the same type grouping together give us tissues; like muscle, nerve and connective tissue.  For example, muscle cells are built to contract, nerve cells are built to pass along electrical charges.  A big tissue is epithelial, made from tightly packed cells forming sheets – barriers to separate bits.

Organs are when you’ve got tissues working together for something specific. The biggest is the skin. Skin is pretty amazing, it has plenty of functions with all the kind of sensors it has.  The liver is the biggest internal organ and it too is amazingly complex with hundreds of vital functions.

Systems of the body are made of a group of organs like the digestive system from mouth, stomach, with a lot of intestines. There’s the respiratory system, cardiovascular, endocrine, immune, skeletal, muscular, lymphatic, reproductive, urinary, nervous… it’s a complex thing the body. This is a good site to learn more about all the different systems and their bits!

The Human Body

There we have the basics of the body, taken down to the littlest bits. Not that you’d put a price on a life, and the body is hugely complex, but if you could sell all the elements – I thought it’d be maybe £100, but a few years ago, the Royal Society of Chemistry ran a competition to guess the value of Benedict Cumberbatch and he went for around £96,500. So who knows your value, you could be worth millions! But let’s just not sell our elements, I mean I’m quite happy with mine?