Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0026838 (spasticity)
 6,471 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

After a brief review of the pharmacological properties of the botulinum toxin (BT), its mechanism of action on the nerve endings of the neuromuscular junctions, and the general therapeutic principles and adverse side effects, we discuss the advantages of interventional neurophysiology for the treatment of focal motor disorders by means of botulinum toxin A (BTA) muscle infiltration. Electromyography (EMG) provides a valuable objective information in the diagnosis of many motor disturbances and enables the precise identification of the muscles that contribute to the abnormal movement or posture. The use of EMG guidance for BTA injection seems advisable in every muscle but it become indispensable in those difficult to access, deeply located or partially atrophied by previous toxin infiltrations. The EMG study also serves to localise the areas with the highest abnormal activity and the motor point of the muscle, where the injection of toxin exerts its maximal effect. Consequently, lower doses of BTA can be employed without decreasing the efficacy of treatment but reducing the potential risk of side effects, antibody production and the cost of treatment. Electrophysiological diagnosis and BTA treatment may be performed during the same exploration. Considerations on the particular aspects and lines of action are given referring to the main focal muscular hyperactivity motor disorders such as cervical, oromandibular and laryngeal dystonias, blepharospasm, writer's cramp, hemifacial and hemimasticatory spasms, infantile and adult forms of spasticity and some other focal disturbances such as strabismus, detrusor-sphincter dyssynergia and anismus.
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PMID:Botulinum toxin in motor disorders: practical considerations with emphasis on interventional neurophysiology. 1159 29

Botulinum toxin is a dreaded biological toxin elaborated by Clostridium botulinum. The action of this toxin is to cause paralysis of both voluntary and involuntary muscles. The unique property of paralysing capability of muscles has been used for the benefit of human beings. Dr Allan Scot, an ophthalmologist, first used the toxin in a patient with squint in 1981 and since then the botulinum toxin is being used in various disorders characterised by muscle overactivity such as spasticity in both children and adult, dystonic conditions such as blepharospasm, cervical dystonia, spasmodic dysphonia, writer's cramp, etc, hemifacial spasm and headache. Its main action is at the terminal nerve endings of myoneural junction and it prevents release of acetylcholine from vesicles thus causing chemical denervation. Its action persists for 3 to 4 months on an average. Its side effects such as drooping, diplopia, dysphagia, depending on the sites of injection, are few and usually transient. Generalised anaphylaxis is almost unknown. Now botulinum toxin is being used in non-neurological conditions where muscles are under spasmodic state such as achalasia cardia, anal fissure, spasm of urethral sphincter, etc. Because of wider safety range and fewer complications, botulinum toxin has been an important therapeutic armamentarium in different branches of medicine and surgery.
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PMID:Botulinum toxin: a dreaded toxin for use in human being. 1245 15

Botulinum toxin has been used for therapeutic purposes in medicine for more than 20 years. Its effective use now covers more than 50 conditions in a wide variety of areas. Its medicinal use was initially based on its blockade of neuromuscular and neurosecretory transfers. Its use for conditions in the field of specific pain therapy is currently authorized in Germany for spastic torticollis, blepharospasm, hemifacial spasm, spastic equine gait in cases of idiopathic cerebral paresis, and spasticity of the arm following stroke. New publications suggest that it can usefully be employed for numerous other painful conditions. The modes of action known today are not confined to the blockade of cholinergic innervation.Indeed, there is also evidence that therapeutic effects are mediated through a normalization of muscle spindle activity, retrograde intake into the CNS with modulation of the central neuropeptide function, inhibition of sterile neurogenic inflammation, and normalization of endplate dysfunction. In view of the methodological peculiarities of studies in the field of pain therapy, such as injection techniques, injection sites, blind study techniques, dosage etc., the scientific evidence for its use in a wide variety of pain syndromes is still patchy in many areas. For this reason the use of botulinum toxin for these syndromes is only justified after full use has been made of standard therapeutic methods and evaluation in specialized centers. The possibility of considering botulinum toxin in specific pain therapy contexts is a new option for patients and doctors.However, its use calls for detailed knowledge of functional neuroanatomy and extensive practical experience and expertise.
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PMID:[Botulinum toxin in specific pain therapy]. 1269 98

Since the introduction of botulinum toxin (BTX) as a therapeutic tool in the 1970s, the number of uses for this substance has increased exponentially. BTX's mechanism of action involves degrading the SNARE proteins blockading the release of acetylcholine into the neuromuscular junction. In many body systems, decrease of contractility, strength, and tension of certain muscle groups result in improved clinical outcomes. Applications now include cosmetic, gastroenterologic, otolaryngologic, genitourinary, neurologic, and dermatologic uses. In fact, BTX can be considered as a potential treatment in any situation involving inappropriate or exaggerated muscle contraction. Currently, the FDA has approved BTX-A (Botox) for treating glabellar lines, blepharospasm, strabismus, hemifacial spasm, cervical dystonia, and spasticity. With the addition of cosmetic applications to the FDA's approval list, the use of BTX has increased dramatically.
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PMID:Noncosmetic uses of botulinum toxin. 1515 50

Spasticity results in a resistance to passive movement and decrease of passive mobility of the involved joints and is defined as a state of hypertonicity with exaggeration of tendon reflexes mediated by a loss of inhibitory control of upper motor neurons. In patients with severe stages of multiple sclerosis (MS) spasticity of the lower limbs often leeds to a spastic pattern with hip adduction resulting in decreased range-of-motion (ROM), increased pain, spasms, and functional disability (disturbed gait and sitting position) as well as difficulties with perineal hygiene. Local botulinum toxin type A (Btx-A) injections in spastic muscles offer a new treatment approach for managing spasticity and associated problems. Up to now Btx-A is approved for the treatment of blepharospasm and cervical dystonia and the treatment of equinous gait in children with cerebral palsy in Austria and Germany. Up to now only in Switzerland Botox is licensed for the treatment of focal spasticity. Btx-A is a neurotoxin derived from Clostridium botulinum. In most european countries Btx-A is available as Dysport (vial = 500 units) and Botox (vial = 100 units). In prospective studies a ratio of 1 unit Botox to 3-4 units Dysport was found. Following intramuscular injection Btx-A blocks the release of acetylcholine at the neuromuscular junctions, thereby inhibiting muscle contraction, and decreases spastic muscle tone and muscle spindles afferent information to the spinal cord. The spectrum of side effects includes local weakening of the injected and adjacent muscles as well as pain and haematoma at the injection site. At therapeutic doses side effects are local and transient. According to a double blind, placebo controlled, dose ranging study published by Hyman et al. (2000, Dysport in a dose of 500, 1000 and 1500 units reduced the degree of hip adductor spasticity associated with MS, and this benefit was evident despite concomitant use of oral antispasticity medication. According to the results of the study there was a clear trend towards greater efficacy and duration of effects with higher doses of Dysport. Taking efficacy and adverse events into account (incidence of muscle weakness was higher for the 1500 units group than for placebo) the optimal dose for hip adductor spasticity seems to be 1000 units Dysport divided between the adductor magnus, longus and brevis muscles and between both legs. To increase Btx-A effects following injection of hip adductors additional physiotherapy and casting or orthosis to increase passive hip-abduction is recommended. According to the literature anatomical localisation of the adductor muscles for injection and aspiration following insertion of the needle, to avoid injection of the toxin into a vessel, should be performed. A maximum dose of 1500 units Dysport (400 units Botox) per treatment session and 250 units Dysport (50 units Botox) per injection site is recommended. See table for dose-range of Dysport, and Botox in the treatment of adult patients with hip-adductor spasticity. For evaluation of treatment effects in hip adductor spasticity clinical examination with specific scales and measurements (see Appendix) at baseline, 4 and 12 weeks following BtxA injection is recommended:--Global rating of severity (0-4; patient's self assessment and physician's rating) --Global rating of response (-4 - +4; patient's self assessment and physician's rating)--Visual Analogue Scale (patient's self assessment of pain)--Active and passive ROM (manual goniometer)--Distance between the medial femur condyles in thigh extension (distance in cm)--Modified Ashworth scale (0-4)--Ten meter walking time (seconds)--Functional Ambulation Categories (0-5)--Score of perineal hygiene (0-5).
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PMID:[Botulinum toxin treatment of hip adductor spasticity in multiple sclerosis]. 1550 48

Since its introduction in the late 1970s for the treatment of strabismus and blepharospasm, botulinum toxin (BoNT) has been increasingly used in the interventional treatment of several other disorders characterized by excessive or inappropriate muscle contractions. The use of this pluripotential agent has extended to a plethora of conditions including: focal dystonia; spasticity; inappropriate contraction in most sphincters of the body such as those associated with spasmodic dysphonia, esophageal achalasia, chronic anal fissure, and vaginismus; eye movement disorders; other hyperkinetic disorders including tics and tremors; autonomic disorders such as hyperhidrosis; genitourinary disorders such as overactive and neurogenic bladder, non-bacterial prostatitis and benign prostatic hyperplasia; and aesthetically undesirable hyperfunctional facial lines. In addition, BoNT is being investigated for the control of the pain, and for the management of tension or migraine headaches and myofascial pain syndrome. BoNT injections have several advantages over drugs and surgical therapies in the management of intractable or chronic disease. Systemic pharmacologic effects are rare; permanent destruction of tissue does not occur. Graded degrees of relaxation may be achieved by varying the dose injected; most adverse effects are transient. Finally, patient acceptance is high. In this paper, clinical experience over the last years with BoNT in urological impaired patients will be illustrated. Moreover, this paper presents current data on the use of BoNT to treat pelvic floor disorders.
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PMID:Management of bladder, prostatic and pelvic floor disorders with botulinum neurotoxin. 1572 17

Clostridium botulinum, a Gram-positive, anaerobic spore-forming bacteria, is distinguished by its significant clinical applications as well as its potential to be used as bioterror agent. Growing cells secrete botulinum neurotoxin (BoNT), the most poisonous of all known poisons. While BoNT is the causative agent of deadly neuroparalytic botulism, it also serves as a remarkably effective treatment for involuntary muscle disorders such as blepharospasm, strabismus, hemifacial spasm, certain types of spasticity in children, and other ailments. BoNT is also used in cosmetology for the treatment of glabellar lines, and is well-known as the active component of the anti-aging medications Botox and Dysport. In addition, recent reports show that botulinum neurotoxin can be used as a tool for pharmaceutical drug delivery. However, BoNT remains the deadliest of all toxins, and is viewed by biodefense researchers as a possible agent of bioterrorism (BT). Among seven serotypes, C. botulinum type A is responsible for the highest mortality rate in botulism, and thus has the greatest potential to act as biological weapon. Genome sequencing of C. botulinum type A Hall strain (ATCC 3502) is now complete, and has shown the genome size to be 3.89 Mb with a G+C content of approximately 28.2%. The bacterium harbors a 16.3 kb plasmid with a 26.8% G+C content--slightly lower than that of the chromosome. Most of the virulence factors in C. botulinum are chromosomally encoded; bioinformatic analysis of the genome sequence has shown that the plasmid does not harbor toxin genes or genes for related virulence factors. Interestingly, the plasmid does harbor genes essential to replication, including dnaE, which encodes the alpha subunit of DNA polymerase III which has close similarity with its counterpart in C. perfringens strain 13. The plasmid also contains similar genes to those that encode the ABC-type multidrug transport ATPase, and permease. The presence of ABC-type multidrug transport ATPase, and permease suggests putative involvement of efflux pumps in bacteriocin production, modification, and export in C. botulinum. The C. botulinum plasmid additionally harbors genes for LambdaBa04 prophage and site-specific recombinase that are similar to those found in the Ames strain of Bacillus anthracis; these genes and their products may play a role in genomic rearrangement. Completion of genome sequencing for C. botulinum will provide an opportunity to design genomic and proteomic-based systems for detecting different serotypes of C. botulinum strains in the environment. The completed sequence may also facilitate identification of potential virulence factors and drug targets, as well as help characterize neurotoxin-complexing proteins, their polycistronic expression, and phylogenetic relationships between different serotypes.
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PMID:Clostridium botulinum: a bug with beauty and weapon. 1583 1

The increasing use of botulinum toxin type-A, especially for focal dystonia and spasticity has highlighted the issue of secondary non-responsiveness. Within the last few years botulinum toxin type-B (Myobloc/Neurobloc) has become commercially available as an alternative to type-A. This paper discusses our initial experience of botulinum toxin type-B in a total of 63 individuals who attended our botulinum clinic. Thirty-six patients had cervical dystonia and a secondary non-response to type-A toxin. Thirteen of these patients (36%) had a reasonable clinical response to Neurobloc and continue to have injections. The other 23 patients either had no response, or a poor response, or had unacceptable side effects and ceased treatment. A small number of people with blepharospasm, hemifacial spasm and foot dystonia also had a disappointing response to injection. Twenty patients with spasticity were also type-A resistant. Seven of these show some continuing response to type-B, without unacceptable side effects. These findings demonstrate that botulinum toxin type-B has a place in the management of patients who have become non-responsive to type-A, but overall the responses to type-B toxin were disappointing.
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PMID:The use of botulinum toxin type-B in the treatment of patients who have become unresponsive to botulinum toxin type-A -- initial experiences. 1632 88

Since its development for the use of blepharospasm and strabismus more than 2.5 decades ago, botulinum neurotoxin (BoNT) has become a versatile drug in various fields of medicine. It is the standard of care in different disorders such as cervical dystonia, hemifacial spasm, focal spasticity, hyperhidrosis, ophthalmological and otolaryngeal disorders. It has also found widespread use in cosmetic applications. Many other indications are currently under investigation, including gastroenterologic and urologic indications, analgesic management and migraine. This paper is an extensive review of the spectrum of BoNT clinical applications.
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PMID:Botulinum toxin: clinical use. 1687 Apr 87

Botulinum toxin type-A (BoNT-A) prevents the release of acetylcholine at cholinergic junctions, thereby causing temporary muscle weakness lasting 3-4 months. It is now widely used to treat a broad range of clinical disorders characterized by muscle hyperactivity. BoNT-A has proved effective in the management of several neurological conditions and, in particular, in the management of movement disorders (e.g. blepharospasm, cervical dystonia, laryngeal dystonia, limb dystonia, hemifacial spasm, focal tics, tremor and other hyperkinetic disorders). As a treatment of spasticity, BoNT-A can improve mobility and dexterity as well as preventing the development of distressing and costly secondary complications. In cerebral palsy, BoNT-A is of value, being able to delay or even avoid surgery until motion patterns have become established.
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PMID:Clinical value of botulinum toxin in neurological indications. 1711 46


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