Posts Tagged ‘lungs’

Breathing Exercises
Breathing is a delicate art, and it is possible to get it wrong, in a variety of ways and for a variety of reasons. A poor breathing pattern can gradually become habitual,

without the person concerned being aware that his or her breathing is at all abnormal.
Allergy and sensitivity reactions sometimes play a part in causing abnormal breathing, and the symptoms produced by a poor breathing pattern may then augment the symptoms of

sensitivity, creating a vicious circle. Correcting an abnormal breathing pattern, by means of breathing exercises and re-training, can produce remarkable improvements in health

for some people.
Breathing too much
Taking in too much air, often called over-breathing or hyperventilation, is the most common breathing disorder. It can produce a variety of rather strange symptoms (see p. 227)

that are sometimes diagnosed correctly, and treated appropriately, but often get overlooked or misdiagnosed.
The primary purpose of breathing is to obtain oxygen from the air and absorb it into the blood. The lungs are a crucial interface here, a trading post for gases that are

exchanged between the bloodstream and the external air. The delicate, moist membranes that cover the inner surface of the lungs are accessed by millions of tiny thread-like

blood vessels known as capillaries. Oxygen from the air seeps into the blood through the thin walls of these capillaries. At the same time, the lungs clean the blood of carbon

dioxide, a waste gas produced by the body’s metabolism. As oxygen seeps into the blood, carbon dioxide seeps out.
That is the school-textbook view of breathing, and it is correct up to a point. But it is over-simplified and misleading if it simply portrays oxygen as totally
good and carbon dioxide as totally bad. In fact, there is a correct level in the blood for both gases, and too little or too much of either can cause problems.
Carbon dioxide plays an important role in the equilibrium of the blood because, when dissolved in any liquid, carbon dioxide makes a weak acid. So the amount of carbon dioxide

present is crucial in deciding the acidity of the blood. Given that the blood reaches every part of the body, it is not surprising that any changes from its normal composition

have far-reaching effects.
Normally, blood is very slightly acidic, and that is what the body is accustomed to. While some body parts can cope with small changes in the acidity of the blood, other parts

respond very badly. The nerve cells are particularly vulnerable to changes in acidity.
Hyperventilation, or over-breathing, has relatively little effect on the level of oxygen in the blood, which is carefully controlled, but it can lower the level of carbon

dioxide in the blood, thus making it less acid. More commonly, hyperventilation just makes the level of carbon dioxide vary a great deal.

When the carbon dioxide levels in the blood yo-yo about all the time, this has some unpleasant effects. In particular, it disrupts the smooth running of the nerve cells, which

is why many of the symptoms of hyperventilation involve the senses, feelings or behaviour.
The symptoms of hyperventilation can include:
•    numbness or pins-and-needles in the hands and feet, occasionally affecting the lips and tongue as well
•    difficulty in swallowing
•    aching muscles, cramps, tremors and twitches
•    sudden loss of strength in the muscles
•    dizziness, confusion, unreal or spaced-outfeelings
•    blurred vision, ringing in the ears
•    headache, migraine
•    breathlessness
•    aching in the chest
•    abnormal heart rhythm
•    sensitivity to bright lights and loud noises.
There may also be some severe psychological symptoms:
•    panic – a brief but intense state of anxiety
•    prolonged anxiety or depression
•    hallucinations, although this is rare
•    mood swings and phobias, most frequently a fear of dying. The irrational conviction that death is imminent can be overwhelming, even in someone who is young and

apparently in good health.
Each of these symptoms can, of course, be caused in several other ways, but when this whole cluster of symptoms – or a large number of them –occurs together in an individual,

that person is very likely to be a hyperventilator.
When there are short self-contained bursts of hyperventilation, the effects are often described as a panic attack. Doctors usually have no trouble recognising this problem, but

– not surprisingly – are often misled by the sustained psychological symptoms of chronic (long-term) hyperventilation. Many people with chronic hyperventilation are diagnosed as

having some kind of mental illness, and they may go for years without getting the right diagnosis.
Hyperventilation and sensitivity reactions The link between sensitivity reactions and hyperventilation seems to be a complex one. Unfortunately, very little research has been

done in this area, so what follows is based on the case-histories of patients, and the collective experience of doctors, not on hard scientific data.
In some cases, a sensitivity reaction may
directly provoke a change in breathing pattern. This
is what appears to happen for some people with
caffeine sensitivity. Cutting out all caffeine-con-
taining drinks (coffee, tea and colas) seems to put a
stop to the hyperventilation symptoms, because the
multiple symptoms promptly disappear (see p. 235).
In other cases, a severe sensitivity problem such
as multiple chemical intolerance results in an anxious
state of mind, and the anxiety leads to hyperventi-
lation. Hyperventilation, pure and simple, may also
masquerade as chemical intolerance (see p. 236).
Wheezy as a mountain breeze
Ionisers — devices that supposedly turn indoor urban air into a fresh mountain breeze — are often promoted as alternative devices that can clear allergens from the air. They do

remove some allergens, but in the case of asthma, research shows that some ionisers can actually make symptoms worse, by generating ozone which irritates the airways. It is

usually the cheaper ionisers that do this. More expensive models are less likely to produce ozone, but they are unlikely to help either. Several scientific trials show that

ionisers have no significant benefits when used by asthmatics.
Hyperventilation and asthma
While hyperventilation can develop in anyone, asthmatics are particularly vulnerable. During an asthma attack, especially a severe one, developing an abnormal breathing pattern

is an entirely understandable reaction. In an attempt to get more air, you may start breathing more rapidly and taking air into the upper chest, using the accessory muscles of

breathing (see p. 230). These muscles should not normally be used when you are at rest — they exist to give you extra breathing capacity when running fast.
As long as the asthma attack lasts, this forced breathing does no harm, because its effects are cancelled out by the narrowing of the airways. But if this over-breathing

persists after the attack has ended, then too much air is going in and out of the lungs, so carbon dioxide levels in the blood begin to fall.
Simply feeling anxious can also trigger off rapid upper-chest breathing. If you get very worried when an asthma attack starts, you may begin hyperventilating just out of

anxiety.
For asthmatics, in addition to the usual symptoms of hyperventilation (see p. 227) there are some subtle effects of hyperventilation that can make asthma worse:
•    The airway muscles (and all other muscles that are not under voluntary control) contract slightly when carbon dioxide levels in the blood fall.
•    Mast cells are quicker to degranulate (see box on p.12) when
there is less carbon dioxide, and this triggers allergic symptoms. Just to complicate matters, one of the symptoms of hyperventilation is breathlessness. Sometimes this is the

most prominent symptom in non-asthmatic hyperventilators, and the doctor overlooks the other symptoms and gives a diagnosis of asthma. In such cases, people are told they have

asthma when they are actually suffering from hyperventilation alone.
Testing for hyperventilation
You can do two simple tests for hyperventilation at home, if you think that it could be playing a part in your symptoms. (If you are asthmatic, only do these tests when you have

no asthma symptoms and your peak-flow reading is good. Make sure your reliever inhaler is nearby, in case of a bad reaction to the test.)
The first test should be done when you have some symptoms that might indicate hyperventilation (see p. 227).
Find a clean paper bag and hold it over your nose and mouth while breathing normally. Any symptoms that are due to hyperventilation should clear up, because, by re-Inhaling the

air that you have just breathed out, you will increase the level of carbon dioxide in your blood.
The second test is done when you don’t have any of the symptoms listed for hyperventilation.
Speed up your breathing, and inflate your upper chest with each breath. Do this for a few minutes. Do any of your usual symptoms appear? If they do, this suggests that they may

be caused by hyperventilation.
If either of these tests indicates hyperventilation, make an appointment to see your doctor. It is important that you should have a proper medical diagnosis, so that you get the

right professional treatment.
Treating hyperventilation
If you hyperventilate, you could be taught a more healthy breathing pattern by a physiotherapist — ask your doctor for a referral. Certain complementary therapists, such as

osteopaths and Feldenkrais practitioners, can also teach good breathing patterns, and so can experienced yoga teachers (see p. 224). A teacher or therapist who works at a

relaxed pace, is not too dogmatic, and helps you to find your own way to healthy breathing, is preferable to one who tries to impose a regimented breathing pattern on you.
On the assumption that most hyperventilators don’t just over-breathe, but also breathe with their upper chest and under-use the diaphragm (see pp. 229-230), all these different

practitioners will take a combined approach — tackling both sides of the problem at once. This represents an important difference from the Buteykc, method (see below).
The Buteyko method
The stated aim of the Buteyko method (also called the Buteyko treatment) is to stop people from hyperventilating. However, Buteykc, practitioners do not work with people who

have the symptoms of hyperventilation, as recognised by conventional medicine (see p. 227). Instead they work with asthmatics — any asthmatics, not just those whose symptoms

suggest that they might be hyperventilators.
The rationale for this is the claim, by the originator of the exercises, Professor Konstantin Buteyko, that asthma is actually caused by hyperventilation. (What is more,

Professor Buteyko cites hyperventilation as the cause of no fewer than 150 different diseases, including allergies, eczema, migraines, insomnia, bronchitis, high blood pressure

and haemorrhoids. However, his treatment is only marketed for asthma.)
The claims made for the success of the Buteyko method in treating asthma are startling. According to one training centre, it can get 97% of asthmatics off most of their drugs

and able to control attacks within a week of starting.
Not surprisingly, this is a bit of an exaggeration. But the real achievements of the Buteykc, method are still quite impressive: an Australian research study showed that during

the course of Buteyko lessons, the overall use of reliever inhalers (e. g. Ventolin) fell substantially and remained relatively low three months later. However, the patients’

average peak flow stayed the same, and 15% of those studied were admitted to hospital with a severe asthma attack during the trial. In the eight months that followed, 30% needed

a course of steroid tablets – indicating a substantial worsening in their condition. In other words, the Buteyko method can give some help to many asthmatics, but the claim that

it can get almost everyone off asthma drugs and free of asthma is just hype.
Professor Buteyko’s claim to have discovered the fundamental cause of asthma is clearly untrue. What he seems to have discovered is that there are many more hyperventilators

among asthmatics than was widely realised, and that they generally show no obvious symptoms of hyperventilation. His other important contribution is to suggest that

mouth-breathing may create a lot more problems for asthmatics than previously recognised.
The Buteyko method has three aspects:
•    unblocking the nose
•    training to breathe through the nose, not the mouth
•    training to take fewer breaths and pause between breaths. Unlike other treatments for hyperventilation (both conventional and alternative), the original Buteyko method

pays no attention to teaching asthmatics to breathe with the diaphragm. However, a few Buteyko practitioners are now beginning to incorporate this aspect of treatment.
If you decide you would like to try the Buteyko method, there are several different options. Classes are the most expensive route, with very high fees being charged. There are

video cassettes you can buy, which are less expensive. Alternatively, there are various books, which are much less costly, and which explain how to do the exercises (see p.

255).
Whichever option you choose, it is vital that you get your doctor’s permission before starting. Ensure that your reliever inhaler is in your pocket while doing the exercises,

because they could provoke an asthma attack. Keep taking your preventer drugs regularly throughout the treatment. If you start to feel much better and want to reduce your dose

of preventer, you must talk to your doctor first.
Don’t follow the Buteyko method blindly, because some of the advice given is dangerous. For example, some Buteyko publications advise you to refuse oxygen if you are taken to

hospital with a severe asthma attack. They claim that oxygen levels in the blood are not reduced during a severe asthma attack, but this is just not true. Measurements clearly

show that the level of oxygen
gets very low, and this is frequently the cause of death.
Another very peculiar Buteyko idea is that you should not try to shift mucus from your airways because mucus ‘protects you’ against losing too much carbon dioxide. This too is

dangerous advice. Accumulated mucus narrows the airways, adding to your asthma symptoms, and it can even block a small airway completely. The part of the lung served by that

airway then collapses – a serious complication that no asthmatic would want.
Using the right muscles
Hyperventilation is often linked with an abnormal way of breathing, in which the wrong muscles are used. This is one common pattern that conventional doctors recognise for

hyperventilators:
•    The main muscle of breathing – the diaphragm (see below) is not used fully
•    The muscles of the upper chest become involved in breathing, even at rest, when they should not be needed
•    There are lots of rapid, shallow breaths
•    The breathing is quite irregular, with deep, sighing breaths from time to time, or frequent yawning.
Even in those who do not hyperventilate, breathing with the upper chest, and/or neglecting the diaphragm, can become a problem. This pattern of breathing is sometimes linked to

anxiety and emotional problems (see p. 230).
To understand what goes wrong, you need first to know about the healthy way to breathe.
The rib-cage and the diaphragm are the work-horses of breathing. You can feel your rib-cage through your skin, and feel its movements, but the diaphragm is far more

inaccessible. It lies below the lungs, but above the stomach and intestines.
In its contracted state, the diaphragm becomes a thick slab of muscle, with a slight curve, like an inverted saucer. When it relaxes, it becomes far more curvaceous, changing to

a shape like an inverted bell. In this shape, there is less space for the lungs above the diaphragm.
If you are breathing correctly, the diaphragm contracts when you breathe in and relaxes when you breathe out. The contraction lowers the dome of the diaphragm, pulling the base

of the lungs downwards and so making them expand.
Breathing out requires no muscular force whatever, as long
as you are just sitting or walking about (and therefore not breath-
ing hard). The lungs are naturally elastic, like balloons, so they
automatically contract and force out the air, once the diaphragm
relaxes into its bell-like shape and stops pulling them downwards.
While you cannot feel the diaphragm itself, you can feel the
effect of its in-breath contraction. As it contracts, the diaphragm
pushes down on the stomach and intestines, so that your abdomen bulges out a little with each breath. Western women, conditioned to admire an unnatural flat-bellied body shape

(unnatural for a woman, that is), often breathe badly because they are trying to ‘hold the tummy in’. This steely tightening of the muscles across the front of the abdomen

opposes the contraction of the diaphragm, and prevents a natural and relaxed in-breath.
The diaphragm should do virtually all the work of breathing in, when you are not exerting yourself much. The upper part of the rib-cage should hardly expand at all and the

muscles that run between the ribs, the intercostal muscles, should not be working.
When you become more active, and therefore need more oxygen, the upper chest automatically starts to expand with each in-breath. At this point the intercostal muscles become

involved, along with a whole team of other muscles in the chest region —these are known as the accessory muscles of breathing.
The effects of an asthma attack
In the grip of a severe asthma attack, you may well start using the accessory muscles of breathing to try to take in more air. If you have frequent attacks, or if this way of

breathing gets to be a habit and goes on between attacks, then the chest may be distorted by the constant use of the accessory muscles, plus the over-inflation of the lungs.

Severe asthmatics often have high shoulders and a `barrel-chested’ look as a result of this. Hyperventilation may also start in this way.
Observing how you breathe
To discover whether you are breathing with your diaphragm or your upper chest, lie on your back with your left hand on your belly, and your right hand on your upper chest. Just

lie still for a few minutes, let your arms relax, then start to pay attention to your hands. When you breathe in, which hand rises? It should be the left hand, with little or no

movement in the right.
Alternatively, bend over and hold the back of a chair with your hands. Your back, head and arms should form a straight horizontal line, at right angles to your legs. Just stay

quietly in this position for a while. It is very difficult to breathe with the upper chest in this pose, whereas breathing with the diaphragm is easy. If you feel fine in this

position, then you are probably breathing well normally.
Correcting upper-chest breathing
Learning to breathe with the diaphragm is often an important part of correcting hyperventilation (see p. 228). It should also be taught to anyone who has the kind of chest

deformities that develop in severe asthma (see above).
Diaphragmatic breathing, or abdominal breathing as it is sometimes called, should help make you feel more relaxed
because the in-breath can disperse tensions in your abdomen. This is where many people ‘hold on to’ their fears, with chronically tense abdominal muscles. When you start

breathing into this area of tension, it is important to take things gently and not force the breath downwards. Be aware of any resistance to the in-breath in the abdomen, and of

any emotional reactions that occur when you challenge this resistance.
Sometimes breathing in this way for the first time can bring up emotional difficulties that may need careful handling. That is why it may be better to learn abdominal breathing

from someone who has time to deal with such issues, and with whom you feel very comfortable and relaxed — for example, a yoga teacher or an alternative therapist who you like

and trust. Physiotherapists tend to take a very brisk and practical approach to breathing, which may not be entirely appropriate or helpful when habitual ways of breathing are

tied up with emotional problems.
When learning to breathe with the diaphragm, be careful not to get carried away and become a ‘belly breather’, whose every in-breath sends the abdomen bulging out like a

mainsail. The abdominal muscles should oppose the downward movement of the diaphragm to some extent, without being too tense.
Clearing the nose
Breathing through the nose, rather than the mouth, is beneficial for asthmatics, because it cleans and warms the air. It can also help those with chronic sinusitis because it

oxygenates the air in the sinuses, which discourages some of the more troublesome microbes responsible for sinus infections.
This technique for clearing a blocked nose, part of a set of breathing exercises for opera singers, is based on a time-honoured yoga exercise called alternate nostril breathing:
•    Sit with your mouth closed.
•    Press your right nostril against your nose to close it, using the thumb of your right hand.
•    Breathe out through your left nostril.
•    Press your left nostril against your nose with the index finger of your right hand, to close it. (The hand makes only a very small movement from side to side.)
•    Breathe in through your right nostril.
•    Repeat the sequence.
Once you have got the hang of this, do ten fairly rapid breaths, with no pause between out-breath and in-breath. Pause and rest.
Repeat using your left hand, and reversing the flow of the breath: out through the right nostril and in through the left. Again, do ten breaths and then rest.
Alternatively, try the following exercise, which is recommend by Buteyko practitioners for unblocking the nose. This technique has not been tested scientifically, but the

reports of asthmatics who have used it suggest that it often works wonders, even with children who could never breathe through their noses previously:
•    Have your reliever inhaler to hand, just in case the exercise brings on an asthma attack.
•    Breathe as you do normally, and at the end of a normal out-breath, close your mouth and hold your nose
•    Stay like this, without inhaling, for as long as you can without discomfort. Walk around the room while you are doing this or, if you are young and fit, do something

more strenuous – either walk upstairs or squat-then-stand several times.
•    When you need to breathe in, keep your mouth shut but release your nose
•    Breathe in slowly through the nose
•    Repeat the exercise if your nose becomes blocked again.
Special exercises for asthma
In addition to tackling the problem of hyperventilation, if one exists, asthmatics can use other breathing exercises to tackle specific aspects of their asthma.
Clearing mucus from the lungs A physiotherapist can teach methods of clearing mucus from the airways which are suitable for asthmatics. Ask your doctor for a referral. You could

also try the following exercises:
Huffing Take an in-breath, then tighten your abdominal muscles very sharply, to push the air out. Imagine there is a candle in front of you, and you are trying to extinguish it,

but using your belly muscles only. Your out-breath should make a short soft ‘huff’ sound – if it is more of a loud ‘w000sh’, you are contracting the muscles in your chest as

well as those in the belly. Try again, and focus your attention on your belly as you make the out-breath.
The in-breath should be effortless with this exercise – it just bounces back in. Do as many huffs as you can without feeling breathless. Rest and repeat. The aim is to build up

stamina until you can do 30 or more huffs in succession.
Pursed-lips breathing Take a fairly deep in-breath, then purse your lips together. As with huffing, your belly muscles have to do all the work of the out-breath, but in this

exercise they are working against the muscles of the lips. The aim is to divide the out-breath into as many fragments as possible – to push the air out through the lips in a

succession of tiny, forceful blasts.
One objective of these exercises is to encourage mucus to start moving up to the top of the airways. From there, it can be cleared with a little throat-clearing cough. Note that

the mucus will probably take a while to reach the throat – this may happen some time after you do the exercise. For maximum effect, repeat these exercises several times each

day.
Coping with asthma attacks
The crucial thing during an asthma attack is to focus on your out-breath, not your in-breath. Of course this goes against the grain, because you feel so desperate for air, but

remember that the central problem is stale air from your last in-breath, now trapped in your lungs by the narrow airways. If you can focus on exhaling this used air, you will

have more space for fresh air to come in with the next in-breath.
At times when you are not suffering from an asthma attack, it is worth doing some exercises that improve the strength of your out-breath. The key problem during an asthma attack

is that the natural elasticity of the lungs, which should power the out-breath, is not equal to the challenge of pushing out all that air through narrowed airways in a short

space of time. In this situation, contracting your abdominal muscles so that they push upwards and assist in emptying the lungs is helpful.
The two exercises described above for clearing mucus –huffing and pursed-lips breathing – also strengthen those abdominal muscles which can assist you with your out-breath

during asthma attacks.
Strengthening exercises
Several different exercises or pursuits that strengthen the breathing muscles seem to produce an improvement in asthma. The reasons for this are not understood.
Asthmatics who take up a wind instrument, such as the flute, often report that their asthma improves considerably. The same effect has regularly occurred with asthmatics who

undertake classical training in singing. One set of exercises, taught to aspiring opera singers and designed specifically to strengthen the diaphragm, has been scientifically

tested and shown to improve asthma and reduce the need for drugs. These exercises can be learned at home (see p. 255). There are also some mechanical devices which can

strengthen the breathing muscles (see p. 255).

Many countries have special schools for children with severe asthma and other allergies. Italian children are sent to one in the Italian Alps, where there is no trace of pollen, house-dust mite, or animal allergens. After nine months these children are a great deal healthier and more active - all their lung function tests are vastly improved. Blood tests show that they are actually less allergic to common allergens than before.
You may not be able to do quite this well at home, but all allergens and irritants can be avoided to some extent. Even if you can’t eliminate them completely, you can certainly reduce your exposure.
Before you start, it is important to be clear about exactly what affects you, otherwise you will be wasting a lot of effort. For example, people who are allergic to dust mite often think that a dusty house will necessarily be worse for them than an apparently clean house, but this is not so (see p. 115). Or they may say ‘Oh, I got asthma on holiday, because the roads were so dusty and I’m allergic to dust,’ forgetting that only house dust contains dust mites. The road dust may have acted as an irritant, and helped to spark the asthma attacks, or it may have contained pollen or mould spores - but it does not contain dust mites or their allergens. Blaming the wrong thing for the asthma attack means that the real culprit is not identified.
If you are not absolutely sure what causes your allergies, skin-prick tests (see p. 91) can identify the allergen. These are especially recommended if your reactions to the presumed allergen are inconsistent, or you don’t respond to the anti-allergen programmes described here. For example, a few people who react to house dust are not allergic to dust mites, but to something else in the dust such as wool fibres or mould spores, or particles from cockroaches, house
flies, carpet beetles or a long-departed cat. Even pollen that has accumulated in house dust can provoke allergic reactions - if you are not an over-keen duster, it can still be there long after the pollen season.
If you have hayfever, knowing which pollens cause your symptoms (and learning to recognise the plants concerned) is useful. You will probably need skin-prick tests to be sure. ‘Hayfever’ can even be a seasonal mould allergy in some people (see p. 27).
Tackling allergens is now big business. There are a lot of people out there competing for your money and false claims are common, especially for anti-mite products. Only a few manufacturers are deliberately misleading, and most false claims probably stem from ignorance or wishful thinking, but be very sure you know the facts about your allergen before you buy.
Air cleaners are a good example. A really good quality air cleaner (which uses a HEPA filter - a High Efficiency Particulate Air filter) is an expensive purchase and, as the advertising tells you, it takes out very small particles with staggering efficiency. But this is entirely irrelevant if the source of those particles is no distance at all from your nose - your mite-infested pillow, for example, or the cat on your lap.
Something else that advertisements for air cleaners rarely mention is that unless you reduce allergen production - tackling mould growth in the house, for example, or keeping the dog outside - the filter can’t help much. In short, air cleaners do have their uses for some allergens, but they can’t work miracles.
The products mentioned here, if not available in your locality, can be bought mail-order from specialist suppliers of anti-allergy products (see p. 255). Note that some offer both very good products and distinctly doubtful products, so judge each item on its individual merits. Ask to see scientific evidence that it works.
Don’t be taken in by vague statements such as anti-allergenic’ - get the facts. This label is often used on pillows with synthetic filling, for example, and people assume that it refers to dust-mite allergy, whereas it simply means that the pillow does not contain feathers. But unless you are allergic to feathers, there is no reason to avoid feather pillows. (In fact, if not covered with mite-proof covers, synthetic pillows collect more dust-mites than feather pillows, because the fabric used for the cover is less tightly woven and the mites and skin particles get in more easily.)
Bad advice is also a hazard. Some of it just wastes your time and effort, but some could actually increase your exposure to the allergen. Advice to vacuum floors daily, or to vacuum beds, is commonplace but this achieves little and it means breathing much more allergen unless you have the right kind of vacuum cleaner. One health magazine even advised its readers with dust-mite allergy to ‘air mattresses by regularly turning them’. This will not affect mite numbers at all, but it will shoot massive amounts of mite allergen out of the mattress and into the nose and lungs.
Ridding your house of allergens and irritants is, in itself, a hazardous procedure because more of the offending substances will be released into the air during the work. If you take up carpets or remove mattresses, dust-mite allergens and mould spores will be churned up in their millions. Just bundling up a duvet will produce invisible clouds of dust mite allergen - and cat allergen, if your pet once slept on the bed.
Ideally, the allergic individual should not do the work, nor be in the house until it is 100% complete and the house has been very thoroughly aired. This is particularly important for those with chronic sinusitis and mould growth in the house, because of the risk of fungal infections in the sinuses (see p. 32).
If you are an allergy sufferer and have absolutely no choice but to do the work yourself, or to be present, then you should get a good quality dust mask and wear it throughout - only take it off when you go outdoors. Those with atopic eczema and sensitivity to airborne allergens should cover their skin carefully -with clothing, not barrier cream.
An ordinary hardware-shop dust mask is not adequate for most allergens - it only takes out really big particles and lets through all the common airborne allergens except pollen. You need a more serious sort of mask, designed for workplace use and conforming to official standards. Before buying one, ask what is the smallest size of particle that it filters out (at 90% efficiency, or better). Compare this with the particle size of your allergen (given in the articles that follow).
You must be able to breathe well through the mask when physically active, and it must fit tightly against your face, forming a seal at all edges. Beards and moustaches tend to prevent this - as does stubble.
Masks that combine an activated carbon filter with a dust filter will take out gases and chemical vapours as well as particles. Cycle shops now sell such masks -or try an industrial supplier. Such a mask can be useful if you are affected by traffic exhaust or industrial pollution as well as an allergen, for example, or if you are exposed temporarily to wet paint or other fumes at home. Activated carbon masks should also filter out the irritant substances from oil-seed rape plants.
Some people who try the anti-allergen programmes feel much better quite fast. But generally these are long-term strategies - you may not reap any benefits for a few weeks, and the improvement may be small at first. Sometimes it takes several months for the full effects to be felt, so be persistent.

Asthma.
Tom works for the Post Office, sorting mail on a night shift. ‘After work, I come out of the sorting office - it’s about five or six in the morning, and really cold - and when I suddenly hit the cold air, I feel as if I just can’t breathe. My chest clamps up like anything, so much that it hurts. Then, when I get in the car and put the heater on, it’s fine again.’
What Tom is describing is bronchospasm, the key event in asthma – a sudden, but reversible, tightening of the bands of muscle that surround the airways. The narrowed airways stop air from leaving the lungs at the normal speed, which means the lungs are still half-full when it’s time for the next in-breath.
Taking more air into half-full lungs produces pain and tightness in the chest, as the lungs become over-inflated. (This can be alarming, because it can seem like pain from the heart, but it is just the rib joints and chest muscles hurting as they become stretched.)
Insufficient oxygen reaches the bloodstream because there is so much stale air in the lungs, so the asthmatic also feels breathless. Meanwhile, the air being forced through the narrowed airways makes a whistling sound called wheezing.
Those are the common symptoms of asthma, but there are others:
• Coughing, rather than wheezing, is the main symptom for some people (see box on p. 40).
• Sometimes there is vomiting during an asthma attack, especially in children, because the
overexpanded lungs put a great deal of pressure on the stomach.
• A few asthmatics suffer narrowing in the trachea (the upper part of the windpipe) rather than
in the airways lower down, and therefore feel as if they are being strangled.
Bronchospasm is just the endpoint of the disease process in asthma, a process which begins with inflammation of the lining of the airways. Although the airway muscles relax when an asthma attack is over, and you therefore feel much better, the underlying inflammation of the airways remains.
Airway inflammation may be caused, or partially caused, by allergy. Among asthmatic children, allergies are detected in 80-90%.
Inflammation makes the lining of the airways swell up, which itself narrows the airways a little. The inflamed airway lining often makes more mucus than usual, in an effort to protect itself (this is basically a healthy response – mucus works like a sponge mopping up irritating dust particles so that they can be ejected by coughing – but it’s excessive in asthma). This mucus can clog up the airways even more. Finally, the inflamed airways send nerve impulses direct to the airway muscles telling them to contract.
Mucus alert
Asthmatic mucus is white or clear, and sometimes frothy. Greenish or yellowish mucus suggests an infection and should be reported to your doctor.
In severe cases of asthma, a lump of mucus can completely block an airway, leading part of the lung to collapse. It is vital to clear mucus from the lungs, and a physiotherapist can help with this.
What causes asthma?
This question can be answered at three different levels:
1 What makes someone predisposed to asthma?
2 What starts asthma off – in other words, what starts the inflammation process in the airways?
3 What triggers asthma attacks (episodes of bronchospasm)?
What makes someone predisposed to asthma?
The predisposition to asthma is partly inherited (see p. and partly a matter of lifestyle: a poor
diet makes asthma more likely (see p. 206), as does too much cleanliness (see p. 21), obesity and lack of exercise.
What starts off the inflammation?
The predisposition to asthma sets the stage, but it does not, in itself, start the inflammation of the airways. That is often begun by an allergic reaction to something in the air – such as house-dust mite or pet allergens.
Alternatively, the initiating factor could be a viral infection, especially a kind known as Respiratory

Syncytial Virus or RSV – there are epidemics of RSV every two or three years. Those predisposed to

asthma may make an abnormal kind of immune response to chest infections caused by viruses, a response

that shifts the balance of the immune system towards Th2 cells (see p. 11) and allergy-type reactions.

Although the infection is defeated by the immune system, some inflammation of the airway lining

remains.
A heavy dose of certain irritants, such as chlorine, or the substances used in spray-painting cars, can

also initiate asthma; this mainly occurs in a workplace setting, causing occupational asthma (see box

on p. 133).
What triggers asthma attacks?
Once the inflammation of the airways has begun, the airways are ‘twitchy’ –oversensitive – and the

airway muscles contract (i.e. bronchospasm occurs) at the smallest provocation. This contraction of the

muscles – an asthma attack –can be caused by irritants in the air, such as tobacco smoke, or a great

variety of other things. The possible triggers range from cold air or the scent of hyacinths, to

thunderstorms, laughter or anxiety – see p. 39 for a full list. Exposure to the allergens that started

the inflammation will also trigger an asthma attack, as will a virus (viral) infection such as a cold

or flu.
For many asthmatics, the breathing pattern is disturbed by the asthma attacks, and may remain abnormal

between attacks. Hyperventilation or ‘over-breathing’ can begin quite easily for asthmatics, and then

adds to the overall problems. It may be difficult to tell if you hyperventilate or not, because your

habitual pattern of breathing will seem normal to you, but there may be tell-tale symptoms such as

dizziness, tingling of the hands and feet, numbness and muscle cramps. For a full list of symptoms see

p. 227.
Mind power
The muscle of the airways is the kind of muscle over which we have no conscious control, like that of

the heart. It is known as involuntary muscle, whereas muscles in the arms and legs, which contract or

relax when we tell them to, are called voluntary muscles. Studies with biofeedback have shown that

asthmatics may, with training, gain some degree of control over these involuntary muscles. Experienced

yoga practitioners are able to influence certain involuntary muscles, including those in the airways.
There are also various ways in which the mind, or a person’s social and emotional situation, can make

asthma worse (see p. 234) but the damaging idea that it is an entirely ‘psychological’ disease is now

discounted.
Allergens and irritants
Understanding the difference between allergens and irritants is important for asthmatics. Allergens are

specific — either pollen is an allergen for you or it isn’t, depending on how your immune system reacts

to it. They are also a basic cause of asthma — they start it off.
Irritants, on the other hand, are non-specific: they affect every asthmatic if sufficiently

concentrated, causing bronchospasm by aggravating the airway lining. And, at the levels usually

encountered, they only cause trouble because the inflammation of the airways has already occurred.

Irritants include cigarette smoke, other smoke and some industrial fumes, ozone (see p. 130), sulphur

dioxide (given off by some foods and drinks — see box on p. 207), fly spray, air freshener and other

aerosols.
Diagnosis
There are four separate aspects to diagnosis:
1 Is this really asthma or something else entirely?
2 Is it combined with other diseases, and how are they affecting the asthma?
3 What is the basic cause of the inflammation in the airways, and can this be avoided?
4 What sort of factors trigger the asthma attacks?
You may not get this full diagnostic programme, but you can probably help in finding answers to some of

the questions.
Is this really asthma or something else entirely?
There are no tests that can diagnose asthma with complete certainty, but the average case of adult

asthma is pretty easy to spot, and the same is true for children over five. It is also true, however,

that some patients now described as asthmatic would have been given a different diagnosis (e.g. wheezy

bronchitis) thirty years ago. To some extent, this is because asthma was under-diagnosed in the past:

doctors were hesitant about giving a diagnosis of asthma, because of the supposed overtones of

psychosomatic disease. Sweeping away that stigma has been of immense value, but certain patients

(especially young children) may now get diagnosed as asthmatic without sufficient evidence. However,

there are also many instances of asthma being missed.
There are two tests that should be carried out before you are given a diagnosis of asthma:
1 Peak flow is the top speed of the outgoing air from your lungs, usually measured with a simple

portable machine called a peak-flow meter. Because of the narrowed airways, asthmatics have a lower

peak flow than normal.
2 The reversibility test depends on measuring peak flow before and after inhaling a beta-2 reliever

drug which relaxes the airway muscles (see p. 152). If the drug improves peak flow by more than 15%,

this strongly suggests asthma.
Asthma may be difficult to diagnose in certain situations:
• In babies, who often wheeze, especially when they have colds or chest infections. This

generally clears up later and does not automatically develop into asthma. There is great controversy

about whether wheezy babies should be labelled ‘asthmatic’ or not, and how bad the wheezing should be

before they are given asthma drugs. Views on this vary, so you may want to see a different doctor for a

second opinion. For older children who wheeze only when they get chest infections, most doctors feel it

is valuable to use asthma drugs – such treatment does not ‘turn wheezing into asthma’
as is sometimes claimed. (There are several things you can do to minimise the chance of early wheezing

turning into asthma later – see pp. 244-9.)
• When the main symptom is coughing (see box on p. 40).
• When asthma occurs only at night. In some asthmatics, even intensive testing reveals no

abnormality in the airways during the day. The only way to diagnose the condition is to use a peak-flow

meter at home, morning and evening.
• When there is a sudden one-off asthma attack in response to a powerful allergen load. This

sometimes happens to hayfever sufferers at the height of the pollen season (especially during

thunderstorms). Some doctors will want to start asthma drugs immediately, but it may be better to get

the hayfever well controlled with antihistamines and see what happens. Often there are no further

asthma attacks.
Then there are conditions that can be mistaken for asthma:
• In children, an inhaled object – such as a nut or part of a toy – becoming stuck in the

airways. In babies it can also be inhalation of milk droplets; if so, the ‘asthma’ comes on mainly

after feeding.
• Post-nasal drip (see p. 29)
• Heiner’s Syndrome – (see p. 72)
• Bronchiolitis: a viral infection (generally caused by RSV –see p. 37) which affects the small

airways (the bronchioles) of babies and toddlers. Unlike asthma, it usually produces fever.
• Gastro-oesophageal reflux (GER), or the rising of acid from the stomach into the oesophagus.

(This is commonly called heartburn, after its most typical symptom, but you can suffer from GER without

having heartburn.) GER can aggravate existing asthma, and it can also be an asthma mimic. Babies,

children and adults can all suffer from this problem. There will usually be clues such as symptoms that

come on at night after a late supper, or whenever lying down.
• Hyperventilation (see p. 227) in non-asthmatics can be misdiagnosed as asthma if it causes

breathlessness.
• Aspergillosis (see box on p. 18)
• Problems with the vocal cords. Habitually contracting the vocal cords on the in-breath makes a

loud wheezing sound and can cause breathlessness. This problem can mimic asthma, but it also affects

those who really are asthmatic. The cause may be psychological.
• Low-level carbon monoxide poisoning, generally from gas fires, which can cause breathlessness

and fatigue.
• Bronchlectasis: stretching and damage to the airways caused by diseases caught in childhood,

such as pneumonia or whooping cough. This causes lifelong breathlessness.
Is it combined with other diseases, and how are they affecting the asthma?
Any allergic problems in the nose will contribute to asthmatic symptoms in the lungs, because there are

nerve-connections between the two. Long-term sinusitis can also make matters worse. Optimum treatment

for the nasal and sinus symptoms (see pp. 28-35) will help considerably with the asthma.
One unlikely source of asthmatic symptoms has only recently been recognised: allergies can develop to

the fungi causing athlete’s foot, or other diseases (see pp. 16-17).
GER (see p. 38) can contribute substantially to asthma. In some people, the reflux causes no obvious

symptoms, apart from worsening the asthma; medical tests can show that reflux is occurring. Your doctor

can advise on this, and on treatment.
For older people, especially veteran smokers, asthma may be part of a larger picture of inflammation

and damage to the air sacs of the lung (emphysema) and/or to the airways (bronchitis). This mosaic of

problems is known as chronic obstructive pulmonary disease (COPD). It may be difficult to tell if there

is asthma present, or how much it is contributing to the overall problem. Since many patients with COPD

are helped by asthma drugs, and trying out the drugs does no harm, doctors often prescribe them just to

see what happens.
What is the basic cause of airway inflammation? Skin-prick tests are usually needed here, to check for

allergic reactions. It may be difficult to get these in Britain, where there is a shortage of

allergists (see p. 89).
Simple detective work may pinpoint allergens without the need for tests. The likely suspects are all

airborne allergens – see p. 28. Remember that the reaction does not generally start as soon as exposure

to the allergen begins: there is a time-lag. So a new dog or cat, or an allergen encountered at work,

may cause no trouble for the first year or two.
Some irritants can also be a basic cause of asthma, but only if encountered in high doses, which

usually occur in the workplace. These are called asthmagens (see box on p. 133).
In all cases, removing the allergen or irritant from the airways should be a top priority. The sooner

you can end the exposure, the more likely you are to shake off the asthma, rather than have it for

ever. Once the inflammation of the airways is firmly established, it just fuels itself – so act

quickly.
In a minority of cases, food sensitivity is the initiating cause of asthma. The reaction to food is

delayed, so the link will not be obvious. Skin-prick tests for the culprit food are usually negative,

so an elimination diet (see p. 194) is needed to diagnose this problem and identify the food concerned.

Those most likely to benefit are brittle asthmatics (those most severely affected) – as many as 60%

have a food sensitivity. There are various other clues that food could be a factor (see p. 69).
When asthma begins in adulthood, there may be no clear initiating cause – it is just a question of

long-term damage and irritation to the airways. But there can be allergens playing a part, so it is

worth investigating this possibility.
What sort of factors trigger the asthma attacks?
Most asthmatics will recognise one or more of these as triggers:
• cold or dry air
• strong smells including perfume and fragrant flowers
• irritants in the air (such as cigarette smoke and other indoor pollutants, traffic fumes,

industrial pollutants); indoor pollution is often the worst, especially if you have a gas cooker

without adequate ventilation, so there is a lot you can do to improve the air you breathe (see pp.

128-30)
• sulphur dioxide given off by preservatives used in some food and drink (see box on p. 207)
• weather conditions, particularly thunderstorms
• laughing, sighing, yawning, coughing or any other altered breathing pattern
• stress or anxiety
• strong emotions such as fear, anger or excitement
• situations or people that evoke unpleasant memories –including traumatic childhood memories;

sometimes psychotherapy is needed to sort out such problems (see p. 233)
• exercise (because breathing hard dries out the airways)
• the allergens responsible for the asthma, e.g. cat allergen
• colds, flu and chest infections.
Recording your symptoms day-by-day should help to identify the triggers that are most powerful for you.

Generally speaking, such triggers should be avoided, but this is not the case for exercise which does

much more good than harm, in the long run – without exercise, your asthma will get far worse (see p.

41).
Take care with aspirin
Aspirin sensitivity can develop unexpectedly in asthmatics, especially those with allergic rhinitis

and/or nasal polyps (see box on p. 28). It can produce a severe, even fatal, asthma attack in someone

who has previously been able to take aspirin (see p. 151).
Treatment
The first and most important aspect of asthma is environmental control – to try to minimise contact

with allergens and irritants. If you are asthmatic and you smoke, you must stop, because this will only

make matters worse by stoking up the inflammation. Any other smokers in the family should accept that

from now on this is an outdoor activity.
One of the aims of good asthma treatment is to calm the airways down, so that they are less sensitive

and ‘twitchy’. This means tackling the inflammation. You can do this with preventer drugs such as

steroids or cromoglycate (see p. 157), or with the new anti - leu kotriene drugs (see p. 159), or you

can simply remove the basic cause of the trouble, if it is a domestic allergen source, such as a cat, a

dog or house-dust mites.
Treating associated diseases such as sinusitis, hayfever, perennial allergic rhinifis, gastroesophageal

reflux (GER – see p. 38) and athlete’s foot (where this is adding to the symptoms – see p. 16) can also

help in reducing the airway inflammation. Eating a better diet may make a further contribution to

calming the airways down (see p. 206).
The second strand of treatment is to deal with bronchospasm (contraction of the airway muscles) when it

occurs. This is done with reliever drugs such as Ventolin and Atrovent (see p. 152). Note that these

only relieve the symptoms of an asthma attack, and do not address the underlying problem of

inflammation. What is more, if used too frequently (more than once a day) they may increase the risk of

a fatal or near-fatal asthma attack (see p. 153).
At one time, reliever drugs were the mainstay of asthma treatment, and were perceived as entirely safe,

while preventer drugs such as steroids were only given to those with severe asthma. All this has

changed, and most asthmatics, other than those with very infrequent attacks, are now given a

pre-venter. If your drug regime has not been reviewed for some time, make an appointment with your

doctor and check that you are getting the best of the modern treatments.
Drug treatment of asthma is not something you can just hand over to the doctor – it requires a lot of

personal decision - making. If you usually get worse when you have a cold, for example, you need to
Just a cough?
For some, coughing is the main symptom of asthma. Known as cough-variant asthma, this is not always

diagnosed correctly, especially in children. For children with recurrent coughing (two or more episodes

per year of coughing without a cold) it may be a long time before the doctor considers asthma. But

other doctors may diagnose a coughing child as `asthmatic’ all too readily, without doing enough tests.

The important point is that asthma involves episodes of bronchospasm – contraction of the airway

muscles. Without this it is not asthma. Bronchospasm can be detected by medical tests such as peak-flow

readings. Wheezing is one possible symptom of bronchospasm, but coughing is another.
If there is only coughing as a symptom, and never any wheezing, this is probably not asthma. Among

children with this pattern of symptoms, allergies are unlikely to be involved. The cause of such

coughing may be:
• in children, the effects of parental smoking
• in those with perennial allergic rhinitis (see pp. 28-9) mucus from the nose running into the

lungs. This is called post-nasal drip and produces a persistent cough.
• in the middle-aged, eosinophilic bronchitis. This is caused by an influx of eosinophils (see p.

19) into the airway lining, causing inflammation. Allergies do not seem to play a part (it is no more

common in atopics than anyone else) and the airway muscles do not contract abnormally. Treatment is

with inhaled steroids.
• in atopics (those prone to allergies), a condition sometimes called atopic cough. It involves

eosinophils congregating in the trachea (windpipe) and bronchi, but not in the lower airways. There is

inflammation but no airway narrowing. Very little is known about this disease at present; it may or may

not involve allergies. Again, inhaled steroids are effective.
• for a few people, habitual coughing. This is usually an expression of some underlying emotional

difficulty and responds to psychological treatments. The cough often has a honking or barking sound.
Any of these can be misdiagnosed as asthma. For patients with eosinophilic bronchitis or atopic cough,

this is no tragedy as they will probably get the right treatment (inhaled steroids) anyway. But if more

exact diagnostic criteria are being used (e.g. a reversibility test – see p. 38) such patients will not

be classed as asthmatic – this is more of a problem because they may not get appropriate treatment.
increase your dose of preventer as soon as a cold appears, to stop airway inflammation before it

starts. You also need to know when an asthma attack is serious enough to warrant calling an ambulance.

A management plan, worked out with your doctor, is a useful aid (see p. 96). Using a peak-flow meter,

night and morning, to monitor your asthma will also be valuable (see p. 97).
The third strand of asthma treatment is to deal with associated problems:
• Panicky reactions during asthma attacks –which make matters infinitely worse – can be dealt

with by meditation, yoga, relaxation techniques or martial arts training (see p. 222).
• Hyperventilation, which plays a much larger role in asthma than previously suspected, can be

tackled by a variety of methods (see p. 228).
• The distortions of the rib-cage that develop in severe asthma can be treated with osteopathy.
• Losing weight, if you are very heavy, will help ease the burden on your breathing.
Exercise and asthma
Exercise-induced asthma is best tackled, paradoxically, by taking exercise. As your fitness improves,

you don’t pant so hard when exercising, so your airways dry out much less. Countless asthmatics will

tell you that once you overcome the first hurdle – of wheezing the minute you start to exercise –

things get a great deal easier. You will need reliever drugs, and possibly extra preventer, to help you

over this hurdle, but it’s worth it. Warming up with a few sharp sprints, separated by a rest period,

will also help. (If you get an asthma attack while exercising, however, you should always stop –

carrying on regardless can be fatal – literally. Always have your reliever inhaler with you when you

exercise and use it if you get an attack.)
Swimming is an excellent starting point for unfit asthmatics, because the moist air prevents the

airways from drying out. Swim outdoors if you can, since chlorine can be an irritant.
Once you are fitter, regular strenuous exercise makes the breathing muscles stronger, which is of great

benefit – this can also be achieved with special exercises (see p. 231).
Don’t underestimate asthma
Asthma can be fatal, so never take it too lightly. If you often wake up in the night with asthma, you

cannot keep up with most other people your age, or are frequently breathless when climbing stairs or

walking uphill, then your asthma is not under control. The same is true if you need your reliever

inhaler more than once a day, or frequently need steroid tablets. Review your treatment with your

doctor because you probably need more preventive treatment such as inhaled steroids (see p. 157) or

anti-leukotriene drugs (see p. 149).
Recognising an asthma attack and knowing when to call for help, or go to the hospital, is also crucial

(see p. 100). Remember that fatal asthma attacks often come on very quickly – half those who die do so

within two hours of the attack starting, and a quarter die within 30 minutes. Those who die are

generally people who have neglected their preventer medication, or have been exposed to very high

levels of allergens.
There is a major organisation involved in asthma prevention, by the name of Asthma UK. They work together with people with asthma, health professionals and researchers, to develop and share expertise to help people increase their understanding of asthma, and asthma prevention, allowing them to voice their concerns to the people who matter and reduce the effect of it on their lives. They are the only charity dedicated to asthma prevention by improving the health and well-being of people with asthma and are funded by voluntary donations, indeed they are responsible for nearly £3m of asthma research each year for the cause of asthma prevention.

A form of asthma prevention can be in the improvements in environmental quality to benefit everyone in the school building because pollutants have a universally negative effect. For example, for the benefit of the students, schools should undertake extensive building repairs, painting, cleaning, and extermination during long vacations. They should replace plastic furniture and carpeting, which often emit pollutants in the form of noxious gases. For further asthma prevention, they should limit use of cleaning supplies and equipment that emit toxic fumes and strong odours which again are pollutants, and require good ventilation when they are used. They should have the entire building (particularly the heating and ventilation system) cleaned regularly to eliminate dust mites, mildew, animal dander, feathers, cockroaches, and other possible asthma and allergy triggers, and make sure that leaks of water and plaster dust are stopped and quickly cleaned up. Additionally the can help in asthma prevention by regularly monitoring the air quality of schools, especially those in sealed buildings and try to increase the ventilation so that pollutants can escape. All this can help with asthma prevention. So whilst schools may not be able to eliminate other pollutants, such as chalk dust, they can, as an act of asthma prevention, find out which of them are triggers for particular students and try to limit the student’s exposure to them. Further, sensitive scheduling can keep students with specific sensitivities away from certain art supplies and animals, which may enhance the education of some students but sicken students with asthma.

As an asthma prevention in Scandinavia, cross-country skiers sometimes wear breathing masks which store the heat and moisture from the air they breathe out and then return it to the air they breathe in. This is helpful in avoiding exercise-induced asthma. Good control of your asthma, whether by breathing in a ‘preventer’ treatment or by avoiding causes of asthma such as house dust mites and pets can have a tremendously helpful effect on exercise-induced asthma. Reliever inhalers can be tremendously helpful in asthma prevention if you use them just before you exercise. This applies especially to the so-called ‘beta-2 stimulants’ such as salbutamol (albuterol) or terbutaline. The benefit should last for hours. Long-acting reliever inhalers are also very helpful; they just work for longer. If you are a competitive athlete or sportsman, you may be concerned about disqualification because you use drugs. The good news is that all the ordinary asthma medicines, used in the medically recommended way and dosage, are acceptable to sporting bodies provided you use them correctly for asthma. The wise thing is to check with your sports authority or sports doctor. Asthma prevention is good asthma management!
There are oral asthma medications that an individual can take to control their asthma, inhaled at the onset of an asthma attack. People with asthma can carry a peak flow meter; a hand-held tool for measuring their air flow to determine whether an attack is imminent, thus requiring their asthma medications. With help from medical providers and age-appropriate printed materials, children can learn to monitor their asthma and self-medicate with their asthma medications. Taking such control of their asthma medications not only decreases its symptoms, but also promotes the children’s feelings of self-confidence, with the management of their asthma and its medications.

There are dozens of asthma medications available in the UK; the most frequently prescribed of these medications being: Ventolin; Bricanyl; Becodite; Pulmicort; Intal and Tilade. The first 2 asthma medications are essentially relievers, whilst the others are preventers. The preventer drugs are taken by an inhaled route and must be taken regularly to gain maximum effect. They belong to either the steroid or anti-inflammatory groups of asthma medications. The reliever drugs do not need to be taken as often; indeed there is evidence to support that these medications are more effective when they are taken only occasionally. Naturally there will be a concern about side effects, but in the main, asthma medications are safe and free from problems.

One such treatment which can have side effects is a steroid called prednisolone; which is taken by tablet form. These asthma medications dampen down and reduces inflammation, swelling and phlegm. There is a soluble form of these medications called Prednesol, which is useful for children and people who struggle to swallow tablets. If used in short courses there should be no risks at all; it is only when these asthma medications are prescribed over a period of years that certain side effects can occur. These include skin changes, thinning of the bones, increased blood pressure, indigestion, ulcers and the development of diabetes. Once again the emphasis is on serious long term prescriptions of these asthma medications and a brief course has no history of causing any of the above side effects.

Asthma is not an allergy as such, but there are asthma triggers, which can be caused by an allergic reaction to any number of incidents. If you have asthma, your air passages are irritable. This means things which are harmless to other people may be asthma triggers to an asthma sufferer. Various asthma triggers include: (i) Emotional stress - people with asthma often say their asthma gets worse if they are upset. (ii) Cold air - if you move from warm indoor air to cold air outdoors it can affect the air passeges. (iii) Pollution, in particular tobacco smoke - e.g. in a pub, can be one of the more common asthma triggers. (iv) Grass pollen - particularly when exposed to a recently mown lawn. (v) House dust mites - often attracted by central heating. (vii) Pet fur - especially during the malting season can affect the air passeges. (viii) Exercise - can provoke narrowing of the air passages. (ix) Infections of the lining of the breathing passages - e.g. colds and ‘flu. (x) Some drugs - especially medicines called beta blockers used for high blood pressure or heart disease have been known to be asthma triggers. (xi) Indigestion - also called gastro-oesophageal reflux, with stomach acid coming up into your gullet. (xii) Laughing - so don’t laugh! (Only joking, but it can happen). All the above reflect the irritability of the air passages in asthma, even if some of them do so in somewhat different ways, they all can be asthma triggers.

There have been significant changes in air quality over the past few decades. Pollution, from the burning of coal, which resulted in emissions of sulphur dioxide and particulate matter has decreased considerably; however, the frequency of peaks of traffic related pollution and the geographical extent of it have probably increased. Episodes of pollution from secondary pollutants, notably ozone, produced by photochemical oxidation, have also increased and this is one of the chief asthma triggers. Moreover, there have also been changes in people’s diet, lifestyle, and in homes and other indoor environments. For example, homes have tended to become warmer and, in this and other ways, much more appealing to cohabitation by dust mites, a real enemy of asthma sufferers. All these can act as asthma triggers. Cinemas and theatres can also surprisingly act as asthma triggers for some people. Research carried out recently found low levels of bacteria and moulds on carpets and seats, but high concentrations of cat allergens; presumably brought in on the clothes of members of the audience. Maybe get a DVD next time!