A Comprehensive Review on Spinal Muscular Atrophy (SMA)

Spinal Muscular Atrophy (SMA) is a genetic disease. Caused by deletion or mutation of SMN1, it is an autosomal recessive motor neuron disease. This disease is characterized by generalized muscle weakness and atrophy predominating in proximal limb muscles. Based on age of onset, it’s phenotype is classified into four grades of severity (SMA I, SMAII, SMAIII, SMA IV). This disease is caused by homozygous mutations of the motor neuron 1 (SMN1) gene, and the diagnostic test demonstrates in most patients the homozygous deletion of the SMN1 gene. Individuals at risk should be tested first and, in case of testing positive, the partner should be then analysed. The management of SMA should properly be followed-up coordination by an expert who is able to plan a multidisciplinary intervention that includes pulmonary, gastroenterology/nutrition, and orthopedic care is recommended. An effort has been made to focus on the diagnosis procedures followed by different effective management alternatives for SMA in the present review.


Introduction
Characterized by degeneration of alpha motor neurons in the spinal cord, resulting in progressive proximal muscle weakness and paralysis, Spinal Muscular Atrophy (SMA) is an autosomal recessive neuromuscular disease. There is 4 subtypes of SMA exist which is identify on the basis of clinical severities [1][2][3][4][5]. With an incidence estimated to be around 1 : 6,000 to 1 : 10,000 in newborns, SMA is one of the most frequent monogenic neurodegenerative diseases [6][7][8]. It affects approximately 1 in 10,000 individuals and is the most common inherited cause of childhood mortality, but this may soon change given recent developments [9]. The U.S. Food and Drug Administration (FDA) approved Spinraza (nusinersen) for the treatment of SMA on Dec. 23,2016. The FDA approved Zolgensma the first gene-replacement therapy for a neuromuscular disease in May 2019. With SMA with bi-allaetic mutations in the SMN1 gene, Zolgensma is a one-time intravenous (into the vein) infusion for the treatment of pediatric patients younger than 2 years of age with SMA including those who are presymptomatic at diagnosis [10].
Zolgensma is the most effective and most expensive drug. Rs. 18 crores is the cost of per dose. With resultant disuse and atrophy of voluntary muscles, Spinal Muscular Atrophy (SMA) is an inherited neuromuscular disorder resulting in anterior horn cell degeneration [5]. SMA is caused by a mutation in the Survival Motor Neuron (SMN1) gene. For proper function of the motor neurons The SMN1 gene produces the SMN protein. The signals from the brain and spinal cord to the muscles telling the muscles to move is send by the Motor neurons. When motor neurons die and fail to send signals, the muscles waste away, or atrophy. Muscle atrophy in SMA can lead to an inability to perform respiratory and motor functions properly [11,12].

2.
Overall muscle weakness, poor muscle tone, limpness or a tendency to flop 3.
In small children: adopting of a frog-leg position when sitting (hips abducted and knees flexed)

5.
Loss of strength of the respiratory muscles: weak cough, weak cry (infants), accumulation of secretions in the lungs or throat, respiratory distress

6.
Bell-shaped torso (caused by using only abdominal muscles for respiration) in severe SMA type 7.
Fasciculations (twitching) of the tongue
SMA 1: SMA type 1, or Werdnig-Hoffmann disease, is a serious condition that usually appears before the age of 6 months. A child may be born with breathing problems, which can be fatal within a year without treatment [15][16][17][18].

SMA 2:
Symptoms of SMA type 2 usually appear at the age of 6-18 months. The infant may learn to sit, but they will never be able to stand or walk. In some cases, without treatment, the individual may lose their ability to sit [15][16][17][18]. SMA 3: SMA type 3, or Kugelberg-Welander disease, appears after the age of 18 months. The individual may have contractures, a shortening of the muscles or tendons, which can prevent the joints from moving freely [15][16][17][18].
SMA 4: It begins after the age of 21 years. The person will have mild to moderate proximal weakness, which means that the condition affects the muscles closest to the centre of the body [15][16][17][18].

Etiology of SMA
People with SMA are either missing part of the SMN1 gene or have a changed (mutated) gene. SMN protein is produced by a healthy SMN1 gene. To survive and function properly motor genes need this protein. People with SMA don't make enough SMN protein, and so the motor neurons shrink and die. As a result, voluntary movements can not be controlled by the brain, especially motion in the head, neck, arms and legs. On chromosome two almost identical SMN genes are present 5q13: the telomeric or SMN1 gene, which is the spinal muscular atrophy-determining gene, and the centromeric or SMN2 gene. By a single nucleotide the coding sequence of SMN2 differs from that of SMN1 (840C>T), which does not alter the aminoacidic sequence but results in alternative splicing of exon 7., SMN2 genes produce a reduced number of full-length transcripts (SMN-fl) and protein due to the alternative splicing of exon 7 , and a variable amount of mRNA lacking exon 7 (10% to 50%, SMN-del7) which give raise to a truncated and unstable protein [19][20][21]. Due

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to deletion or gene conversion of SMN1 to SMN2 about 95% of the patients have homozygous disruption of SMN1 [22]. About 3% of affected individuals are compound heterozygotes for deletion of one SMN1 allele and subtle intragenic mutations. All patients, however, retain at least one copy of SMN2, generally 2-While the severity of the loss of SMN1 is essential to the pathogenesis of SMA loss of SMN1 is essential to the pathogenesis of SMA. While type 3 and 4 generally have three or four, most SMA type I patients have two copies of SMN2, three SMN2 copies are common in SMA type II [23,24].

Diagnosis of SMA
For the diagnosis of SMA particularly in the severe variant of a floppy baby or weak child clinical features are highly suggestive.. The intellect and attentiveness are always good. The weakness is usually symmetrical and more proximal than distal; generally, it is less in the arms than in the legs. By following methods the diagnosis of SMA is mostly undertaken [25,26].

EMG test:
The electrical activity of a muscle or a group of muscles is measured by Electromyography test.

Creatin kinase test: This test measures the high levels of Creatin Kinase. This enzyme is released into the bloodstream by deteriorating muscle.
Biopsy: Doctor removes small amount of muscle tissue and send to it laboratory for examination in this test [26].

Treatment for SMA
Due to the resulting phenotypic spectrum of SMA it is generally considered as a systemic disease [27]. The patients with SMA requires the symptomatic management of respiratory, nutritional and gastroenterological, orthopedic, and psychosocial issues [28]. Nonetheless, the implementation of standards of care is highly variable and is influenced by cultural perspectives, socioeconomic factors, and the availability of regional resources [29]. An updated version of recommendations on diagnosing SMA and patient care was published only recently due to advanced and improvements in care over the last decade [30,31]. The FDA has approved three medications to treat SMA: Nusinersen (Spinraza), onasemnogene abeparvovec-xioi (Zolgensma) and risdiplam (Evrysdi) [32]. Antisense oligonucleotides Trusted Source (ASOs) are the drugs where spinarza belongs which aim to target the underlying problem by influencing the production of RNA. Genentech developed a drug who is also a member of the Roche group, Evrysdi is another effective agent for SMA which was developed in partnership with SMA Foundation and PTC Therapeutics [32].
A one-time AAV-9-based gene transfer therapy which introduces a full copy of the SMN1 gene is Onasemnogene abeparvovec. For the treatment of Spinal Muscular Atrophy (SMA) in paediatric patients, it is the most expensive medicine in the world. It was observed after approval and reported an unprecedented survival rate at 24 months follow-up and unexpected acquisition of motor milestones in 12 patients with infantile-onset spinal muscular atrophy type 1, the most severe type of the disease [33]. After several investigations, including approaches to increase muscle strength and function by hyperacetylating agents such as valproic acid [34][35][36] or phenylbutyrate [37], anabolic agents such as albuterol [38], thyreotropin-releasing hormone [39] or growth-hormone [40] and neuroprotective agents such as gabapentin [41,42], riluzol [43] and olesoxime [44]. Actual therapeutic developments can be subdivided into therapies aiming to modify the splicing of SMN2, replacing the SMN1 gene, or upregulating muscle growth. Figure 2 summarizes the therapeutic approaches discussed in the following sections and illustrates the respective molecular mechanisms of action [20].

Conclusion
No disease modifying treatments are yet available despite our major progress to curb the infants' death from the most common genetic disease of the spinal motor neutron. Several SMArestoring therapies are currently in the early phase clinic trials. The most effective treatment is costly and consequently research unaffordable. Gene therapy is allowing the clinical course to be substantially modified for the first time in the history of SMA. Additional therapeutic approaches are currently being taken at advanced stages of clinical development and are likely to expand the spectrum of drug treatment options for SMA. This will add to the complexity of care for patients with SMA. A timely diagnosis and treatment initiation are particularly important to achieve maximum treatment effects. To attain this goal, although it remains unclear when treatment should be initiated in patients presenting high numbers of SMN2 copies. With early onset SMA, the children show a higher rate of scoliosis during the first years of live despite the improved survival and motor developments of symptomatic patients. Greater awareness of this risk, and close monitoring of spinal deformities appear crucial to react early and enable the spine to be stabilized via medical orthoses. As many braces interfere with breathing in the more severely affected patients, choosing the ideal device can be difficult. Surgical interventions entailing 'growing rod' systems have been reported to be feasible in children with SMA1. Further experience in this field however is needed to balance the risks and benefits of these interventions. There are orthopedic devices for example standing frames -have not been used in most SMA type 1 patients, but they appear promising for the prophylaxis of joint contractures and to allow age-appropriate positioning even in more severely affected patients. This review may be a source to establish better management of SMA keeping in view the recent success of drug treatment in SMA, since many patients are left with a significant disease burden despite drug treatment.