What is Spinal Muscular Atrophy Type 1?
Spinal muscular atrophy (SMA) is a genetic condition which affects the nerves that control muscle movement – the motor neurons.
It is named ‘spinal’ because most of the motor neurons are located in the spinal cord. ‘Muscular’ is in the name because it primary affects the muscles which don’t receive signals from the motor neurons. ‘Atrophy’ is the medical term for wasting away or getting smaller, which is what generally happens to muscles when they’re not active.
There is wide variability in age of onset, symptoms and rate of progression of SMA and it is often classified into types 1 to 4 based on the physical milestones achieved. Please see the document ‘Spinal Muscular Atrophy – an overview’ for a brief description of the different types.
Babies born with the most severe type of SMA – Type 1 – are not able to sit up unsupported and the majority don’t survive beyond the age of two years. Intellect is normal and it is often observed that babies with SMA are bright, alert and responsive. SMA type 1 is also known as Werdnig-Hoffman disease and infantile onset SMA.
SMA is a relatively common ‘rare disorder’ approximately 1 in 6000 babies born are affected, and about 1 in 40 people are genetic carriers. SMA type 1 is the most common type of SMA.
In this factsheet:
• What are the symptoms of SMA type 1?
• What Causes SMA type 1?
• How is SMA type 1 diagnosed?
• What can we expect for the future?
• What research is being done?
• I am a carrier of the SMA gene – what can I do?
• Further information
What are the symptoms of SMA type 1?
The symptoms of SMA type 1 include:
• Muscle weakness and poor muscle tone
• Poor head control
• Weak cry and cough
• The legs tend to be weaker than the arms
• Swallowing and feeding difficulties
• Increased susceptibility to respiratory tract infections
• Developmental milestones, such as lifting the head or sitting up, can’t be reached.
Children with SMA type 1 are diagnosed usually before 6 months of age, more often before 3 months of age. Symptoms may even start in the womb – many mothers later recall the baby not moving as much the last month or so of pregnancy. They are not able to hold up their heads, roll over, crawl, sit up without support, or walk. All of their muscles are extremely weak, with the weakest muscles being the legs, upper arms, and neck. Their body may appear bell-shaped – concave, or very skinny at the top, with a big belly. The strongest breathing muscle in infants with SMA type 1 is the diaphragm and as a result, they appear to breathe with their stomach muscles. SMA affects all muscle systems including sucking, swallowing, digesting food, and excretion.
Generally speaking, the child’s survival depends on the age of onset of the condition. The earlier the symptoms appear, the shorter the expected life-span.
Is there a treatment?
Sadly SMA type 1 is a fatal disorder and there is no cure. However, research for a treatment is moving forward at a fast pace (please see below) and there are things that can be done to support the child and their family so that they can achieve the maximum quality of life.
A multidisciplinary team of healthcare professionals will be needed to manage the symptoms of SMA. The team may include specialists in neurology, genetics, palliative care, respiratory medicine, physiotherapy, occupational therapy, speech and language therapy and gastrointestinal /dietetics. A care coordinator may be available to help you manage care with all of these professionals.
Physiotherapy and occupational therapy
A physiotherapist can give you passive exercises to do which involve moving your child’s body, enabling movements that they are unable to make on their own. Babies will enjoy these movements and they are also very good for their circulation and help prevent stiffening of the joints. Respiratory exercises are very important. Chest physiotherapy is a method of clearing the lungs of accumulated mucus by using positioning and clapping on the chest to assist in loosening secretions. They help to clear the chest when babies have difficulty in coughing and help to reduce the effect of chest infections.
There is a lot that can be done to stimulate a baby with SMA type 1’s cognitive, physical and emotional development. Using balloons and feathers as toys makes for wonderful stimulation and allows them a feeling of independence and accomplishment. For more play and toy ideas please see the link at the end of this document. Your physio/occupational therapist can also suggest ideal seating systems so that your child is comfortable and can move to the best of their ability.
Hydrotherapy can also be of excellent benefit to babies, as they can really enjoy the sensation of moving in warm water. Be careful though, that the child’s head/face does not go under the water so that there isn’t a risk of fluid being breathed into their lungs.
Respiratory health and nutrition
Babies with SMA often have difficulty clearing mucus from the back of their throats so you may be provided with a suction machine. Suctioning involves passing a thin, plastic tube to the back of the mouth to remove all of the mucus collecting there. A weak cough can also make it difficult to clear mucus from the airways. Devices are available such as the “CoughAssist” to help with this.
Weakness of the respiratory muscles can mean that help is needed with breathing. Doctors will use a variety of tests to monitor the breathing so that it can be decided when intervention is required. Portable, effective ventilation devices are now available which can greatly improve quality and length of life. Children with SMA type 1 usually require breathing support while sleeping. Some children require more breathing support, especially with colds. There are several types of ventilator to consider which will be explained by your doctor.
In case of illness a plan of action should be put in place. Even a minor respiratory illness can be life threatening for a baby with SMA. Rapid access to specialist medical care providers should be arranged. Routine immunisations, including influenza vaccine, are also recommended.
When swallowing becomes difficult and the risk of choking a problem, a feeding tube may be introduced. The two possible options are:
– Nasogatric Tube (NG-Tube): a surgically placed tube through the nose that goes directly into the stomach
– Gastrostomy Tube (G-Tube): a surgically placed tube through the skin that goes directly into the stomach.
All of these interventions can seem a little daunting at first, and may cause you distress, but they can help to improve comfort and quality of life for your baby. However, it is important to understand your rights when it comes to making life-sustaining decisions for your child. Be sure that both parents discuss their feelings about this very delicate topic. It is a decision that cannot be made lightly and all options should be covered. Talking to a counsellor in the department of social services at your hospital may be helpful. Once your decision has been reached be sure that you put it in writing, and that all necessary medical personal and family members are aware of your wishes. This is your decision, one you have reached with great care and anguish, and under no circumstances should you allow others to judge you or place their values upon you.
What Causes SMA type 1?
SMA is a genetic condition caused by changes to a gene called ‘survival motor neuron 1’ (SMN1) which is located on chromosome number 5. For an individual to have SMA, they need to inherit two altered SMN1 genes – one from their mother and one from their father). This is what is called an ‘autosomal recessive’ inheritance pattern.
The parents of an individual with SMA each carry one copy of the altered SMN1 gene, and are known as ‘carriers’, but they typically do not show signs and symptoms of the condition. Their other ‘good’ copy of the SMN1 gene is enough to keep the motor neurons healthy. In order for carrier parents to have a child affected by SMA, both parents must pass the altered SMN1 gene on to their child. If both parents are carriers the likelihood of a child inheriting the disorder is 25 percent, or 1 in 4. About 1 in every 40 people is a carrier of the altered gene that causes SMA.
The SMN1 gene change (often called a mutation) usually involves the entire gene being missing or occasionally some of the code of the gene is altered so that the gene doesn’t work. The role of the SMN1 gene in the body is the production of a protein called Survival of Motor Neuron (SMN). If this protein isn’t produced in sufficient amounts, motor neurons start to die. Motor neurons are nerve cells in the spinal cord which send out nerve fibres to muscles throughout the body and control their movement.
But why do some people have less severe types of SMA? This is primarily due to the presence of another similar gene called SMN2. This gene produces several different versions of the SMN protein; however, it only produces a small amount of the full size and functional version. Some people have more copies of the SMN2 gene which results in significant amounts of SMN protein being made. As a general rule, children with SMA type 1 have only one or two SMN2 gene copies and insufficient amounts of SMN protein are produced to protect the motor neurons. People with SMA types 2 to 4 have more than two copies of SMN2 which results in less severe and more slowly progressing symptoms.
SMA severity also may depend on levels of other proteins that people naturally produce in their body. These are called ‘disease modifiers’. Two such proteins that have been identified so far are ‘plastin 3’ and ‘ZPR1’. Patients who naturally produce higher amounts of these proteins tend to have less severe symptoms, but more research is required to fully understand this.
How is SMA type 1 diagnosed?
Babies with SMA type 1 are usually diagnosed before six months of age. If symptoms and a physical examination suggest that a baby might have SMA the first diagnostic test to be done is a blood test which looks for the presence or absence of the SMN1 gene. In approximately 95% of patients with SMA there is complete absence of the SMN1 gene.
If the genetic test shows that the SMN1 gene is present, further physical examination is done to look for symptoms indicative of rare types of SMA caused by mutations in other genes.
Other laboratory tests may also be done to rule out other neuromuscular conditions, which may include:
• Electromyography (EMG) which measures the electrical activity of muscle. Small recording electrodes (needles) are inserted into the patient’s muscles, usually the arms and thighs, while an electrical pattern is observed and recorded.
• Nerve conduction velocity test (NCV) is performed to help assess how well the nerves are functioning in response to an electrical stimulus. Small shocks are repeatedly administered to help assess nerve integrity and function.
• A blood test for the muscle enzyme ‘creatine kinase’– a positive result may indicate a muscular dystrophy.
• Occasionally, doctors may request a muscle biopsy.
If these tests suggest a motor neuron disease, then further genetic testing for SMN mutations should be pursued. In two to five percent of patients with SMA the SMN1 gene is not missing but some of the code of the gene is changed rendering it inactive. Testing for this type of mutation is more complicated so it may take some time to obtain a result.
What can we expect for the future?
Babies with SMA type 1 typically do not survive more than three years and more than half die in the first year of life. In general the later the symptoms begin, the milder the course of the disease is likely to be. Today most doctors now consider SMA to be a continuum and prefer not to make rigid predictions about life expectancy or weakness based strictly on age of onset.
There is a wide range of variability in the symptoms and severity of SMA. This is crucial to remember when considering different aspects of an individual’s care. No two children will be exactly the same and thus treatment and care plans for each family should be tailored to meet their individual needs.
Ideally children need a team of clinicians that specialise in SMA and its specific complications to look after their medical needs and allow them to live life to the full. Individuals with SMA and their family members work together with these interdisciplinary teams to create goals and personalised plans of care that best meet their needs as they change throughout the journey with SMA.
The brains of children with SMA are not affected at all and should be encouraged to participate in as many age- and developmentally-appropriate activities as possible, with adaptations made whenever necessary.
What research is being done?
It is an exciting time for SMA research with several clinical trials underway to test promising new potential treatments. Although clinical trials might not always involve children with SMA type 1, it is expected that if a therapy proves to be effective for one type it may also be applicable to SMA type 1.
The aim of gene therapy for SMA is to introduce a healthy synthetic copy of the SMN1 gene into the motor neurons so that SMN protein can be made. Effective delivery of the gene to the difficult-to-access motor neurons has been considered an almost impossible challenge until very recently. Several research groups published results of experiments in 2010 and 2011 showing that a virus called ‘adeno-associated virus type 9’ (AAV9) is effective at delivering the SMN1 gene to the motor neurons of mice when injected into the blood stream. The gene therapy dramatically improved the life span and motor function of mice that had severe SMA.
In June 2014 a phase 1 clinical trial of this type of gene therapy for SMA was started by US company Avexis Inc. The trial will involve about nine SMA type 1 patients younger than nine months of age. More information about the trial is available on the clinicaltrials.gov website.
Utilising the SMN2 gene
Several research strategies involve manipulating the genetic instructions provided by the SMN2 gene so that more full-length SMN protein can be made. Some researchers are discovering potential drugs in what could be a considered a ‘trial and error’ approach – testing thousands of molecules to find any that increase production of SMN protein. Others are using a more targeted approach – specifically designing drugs to alter the way the SMN2 gene works.
One example of the former approach is a potential drug called RG 3039. Screening of over 500, 000 potential drugs by researchers in the USA discovered a type of compound that was capable of increasing the production of full-length SMN protein from the SMN2 gene. The composition of this compound was then optimised to produce the drug RG3039 which was tested in mice. It was shown to improve the lifespan and various disease symptoms including motor neuron survival in the mice. RG3039 is now being tested by Repligen Corporation in Phase 1 clinical trial in healthy volunteers to determine the safety and pharmacokinetics (see glossary below) of the drug. It is hoped that the information gained from these Phase 1 trials will aid in the future design of clinical trials of RG3039 in SMA patients. Pharmaceutical company Pfizer has now bought the licence to RG3039 and will continue the development and testing. RG3039 is also known by the names PF-06687859 and Quinazoline.
Using the more targeted approach is Isis Pharmaceuticals who are currently testing a potential drug called ISIS-SMNRx in clinical trial. ISIS-SMNRx is an antisense oligonucleotide (AONs) – small pieces of genetic material that can specifically manipulate the way that the genetic code is read. The aim of using AONs for SMA is to encourage the cells to produce more of the full length SMN protein from the SMN2 gene. Administration of ISIS-SMNRx to mice with SMA was shown to target many neuromuscular symptoms leading to a large increase in survival.
Isis Pharmaceuticals has reported positive results part-way through two clinical trials f ISIS-SMNRx. The first of the ongoing trials aims to test two different doses of ISIS-SMNRx in infants with SMA type 1 and the second aims to test four different doses in children with the less severe types 2 and 3 SMA. In both studies the results are encouraging with the children faring better than the typical course of the disease. Importantly, ISIS-SMNRx has been well tolerated.
The ISIS-SMNRx trials involve only a small number of participants and assessments have only been made over a short time period, so further clinical trials will be needed to further assess the safety and effectiveness. However, the results so far are encouraging enough for plans to already be in place to start larger Phase 3 studies. More information on the ISIS clinical trials.
Protecting motor neurons
Olesoxime (TRO19622) is a cholesterol-like compound being developed by Trophos, a French pharmaceutical company. Olesoxime has been shown to protect nerve cells from damage and improve neuronal growth and function, effects that could prove beneficial to SMA patients.
Following a successful phase 1 trial, Trophos conducted a larger phase 2 trial involving 165 people with SMA types 2 and 3, aged between three and 25 years. Results were announced in March 2014. The trial showed that loss of motor function was prevented in those taking olesoxime for two years while those taking the placebo had the typical progressive loss of motor function. Participants taking the olesoxime also had fewer of the medical complications that are normally associated with SMA such as lower respiratory tract infections. The safety of olesoxime was also confirmed and Trophos plans to file for regulatory approval in both the US and Europe as soon as possible. More information about the Olesoxime trial.
Ongoing searches for new drugs
There are many ongoing efforts to identify other new drugs for SMA, both in research institutions and by pharmaceutical companies. Companies involved include Novartis, Merck, Roche and PTC Therapeutics. In August 2013 PTC Therapeutics announced that it had selected and will continue to develop a candidate drug that has the potential to treat SMA.
Another treatment strategy that is being actively investigated in SMA is to use stem cells to replace the motor neurons that have died. SMA mice treated with stem cells displayed increased survival and improved mobility, as well as increased motor neuron number. Research is ongoing to understand the best type of stem cell to use, how to produce these cells in large numbers and how to control their development into motor neurons. California Stem Cell Inc. is particularly active in this area.
One of the big challenges of developing a therapy for SMA is proving that a therapy works. The severity of symptoms from one patient to the next is very variable which makes it difficult to measure whether a new drug works. In addition, SMA type 2 and type 3 patients often have stable muscle strength for months and years making the detection of meaningful changes difficult, whereas infants with SMA type 1 are often too sick to take part in muscle strength tests.
Preclinical research has shown that the timing of treatment may also be critical – early treatment, before too many motor neurons are lost, is likely to be most successful. The window of opportunity for treatment of people with SMA is not known which makes it difficult to plan clinical trials that will give positive results. If a successful treatment is found it may be beneficial for a newborn screening program for SMA to be introduced so that treatment can be started before symptoms appear and the motor neurons are lost.
NOTE: Research is moving forward at a fast pace, so this research summary may not be up-to-date at the time of reading.
I am a carrier of the SMA gene – what can I do?
If you find you are a carrier of the SMA gene, it is recommended that you seek the advice of a genetic counsellor. The genetic counsellor can help you to better understand the risks and chances of having a child with SMA. If you already have a child with SMA, the counsellor can discuss with you options that you may want to consider regarding future pregnancies.
Preimplantation genetic diagnosis (PGD) is an option that might be considered by some couples who are carriers of SMA. This involves using IVF to fertilise eggs outside the body and then testing the resulting embryos for the genetic mutation. Unaffected embryos are then chosen to be placed back in the woman’s womb. Another option is prenatal diagnosis – testing the foetus once the woman is pregnant. The couple then has the option whether or not to continue the pregnancy if the foetus is affected. Alternatively some couples may choose to use egg or sperm donors, or adopt a child.
• More research news on the MDA website
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