Ignite Creation Date:
2025-12-25 @ 1:27 AM
Ignite Modification Date:
2025-12-25 @ 11:38 PM
Study NCT ID:
NCT07180394
Status:
NOT_YET_RECRUITING
Last Update Posted:
2025-09-18
First Post:
2025-08-11
Is NOT Gene Therapy:
False
Has Adverse Events:
False
Brief Title:
Botulinum Toxin for Strabismus Treatment
Sponsor:
Foundation University Islamabad
Organization:
Study Overview
Official Title:
Botulinum Toxin for Strabismus Treatment
Status:
NOT_YET_RECRUITING
Status Verified Date:
2025-09
Last Known Status:
None
Delayed Posting:
No
If Stopped, Why?:
Not Stopped
Has Expanded Access:
False
If Expanded Access, NCT#:
N/A
Has Expanded Access, NCT# Status:
N/A
Acronym:
Botox Squint
Brief Summary:
The bacterial species Clostridium botulinum produces a class of neurotoxins known as botulinum toxin. At the neuromuscular junction, botulinum toxin A prevents acetylcholine from being released. Following a Botox intramuscular injection, the injected EOM becomes paralysed 2-4 days after the injection and remains so clinically for at least 5-8 weeks. Muscle function recovery takes five to fourteen weeks, depending on the injection site, volume, and concentration of the solution, as well as the innervation density.
Botulinum toxin treatment results in a pharmacologic recession of the injected extraocular muscle, and the muscle lengthens while its agonist contracts, paralysing it. Improved ocular alignment or a decrease in the severity of the deviation may last for a long time, even if the pharmaceutical impact normally goes away after three months.
Even after the pharmacologic effect has worn off, a number of elements, such as mechanical, proprioceptive, and binocular effects, may intervene during the period of muscle paralysis to help stabilise and improve alignment in strabismus patients over the long term.
Botulinum toxin treatment results in a pharmacologic recession of the injected extraocular muscle, and the muscle lengthens while its agonist contracts, paralysing it. Improved ocular alignment or a decrease in the severity of the deviation may last for a long time, even if the pharmaceutical impact normally goes away after three months.
Even after the pharmacologic effect has worn off, a number of elements, such as mechanical, proprioceptive, and binocular effects, may intervene during the period of muscle paralysis to help stabilise and improve alignment in strabismus patients over the long term.
Detailed Description:
Detailed Description: A Strabismus or squint is an ocular condition characterized by misalignment of the eyes. It derived from the Greek word "strabismos" meaning 'to look obliquely'. It can be categorized as congenital or acquired, based on onset; by direction; as concomitant or incomitant/paralytic; and as isolated or syndromic. The prevalence of strabismus in the general population ranges from 2-5%, with a lower prevalence of 0.6% observed in the Asian population.
Normal ocular alignment depends upon the integrity of the extraocular muscles, orbital connective tissues, cranial nerves supplying these muscles, fusion centers, and the visual cortex. The etiopathogenesis of strabismus involves abnormalities in binocular vision or neuromuscular control of ocular motility. Left untreated and unrecognized, strabismus can result in irreversible visual impairment, amblyopia, and abnormalities with binocular vision. Moreover, it can significantly impact the affected individual's personality and lead to undesirable cosmetic concerns, such as misdirected eyes, abnormal facial and head posture, and occasionally, peculiar eye movements like up-shoots or down-shoots. It also has psychosocial implications for those affected by it.
The standard therapy for strabismus is either correction of the refractive errors causing it or strabismus surgery under general anesthesia in our country. For optimal benefit, adjustable strabismus surgery is done for cooperative children and adults. This requires 4-6 hours for the general anesthesia to be worn off and may not be an option for very small children and babies, for whom optimal results may not be obtained, in addition to long general anesthesia time.
For more than thirty years, botulinum toxin A has been utilised as a pharmaceutical treatment for strabismus. The majority of the literature on strabismus views it primarily as a surgical substitute, contingent on the strabismologist's preference. But as time and experience have shown, Botulinum toxin is not just an alternate treatment; it also has some other indications in which surgery is not a smart choice. Although there are few randomised controlled trials, Botulinum toxin appears to work similarly to surgery for certain motility issues. Botulinum toxin produces a "chemodenervation" effect, inhibits the release of acetylcholine, and tampers with calcium metabolism. The paralytic effect lasts for two months after injection into an EOM, with the maximal effect occurring in five to seven days. BTXA's overall weakening impact lasts for six to nine months. It is anticipated that the antagonist will experience a relative contraction when under the influence of Botulinum toxin.
Although Botulinum toxin has a short-term impact on extraocular muscles (EOM), it may lead to a long-term reduction in deviation. Potential explanations for this long-lasting effect could include changes in the number of sarcomeres during its effect, immunohistochemical modifications, and central adaptive mechanisms that show up as better binocularity.
The primary goal of this study is to examine the efficacy and outcomes of botulinum toxin intramuscular injection therapy in the treatment of pediatric or adult strabismus, instead of performing surgery in these patients.
Our plan to use the Botulinum toxin in various doses by injecting it into the overacting extraocular musces in strabismus patients, especially pediatric, but also adult cases, to use it as an alternative for strabismus surgery. For children, it will be administered under sedation or general anesthesia and in adults, under topical anesthesia under sterile aseptic techniques. The preoperative and postoperative measurements of the type of strabismus, patterns, deviation, and post-operative results will be studied both in the short and long-term.
Normal ocular alignment depends upon the integrity of the extraocular muscles, orbital connective tissues, cranial nerves supplying these muscles, fusion centers, and the visual cortex. The etiopathogenesis of strabismus involves abnormalities in binocular vision or neuromuscular control of ocular motility. Left untreated and unrecognized, strabismus can result in irreversible visual impairment, amblyopia, and abnormalities with binocular vision. Moreover, it can significantly impact the affected individual's personality and lead to undesirable cosmetic concerns, such as misdirected eyes, abnormal facial and head posture, and occasionally, peculiar eye movements like up-shoots or down-shoots. It also has psychosocial implications for those affected by it.
The standard therapy for strabismus is either correction of the refractive errors causing it or strabismus surgery under general anesthesia in our country. For optimal benefit, adjustable strabismus surgery is done for cooperative children and adults. This requires 4-6 hours for the general anesthesia to be worn off and may not be an option for very small children and babies, for whom optimal results may not be obtained, in addition to long general anesthesia time.
For more than thirty years, botulinum toxin A has been utilised as a pharmaceutical treatment for strabismus. The majority of the literature on strabismus views it primarily as a surgical substitute, contingent on the strabismologist's preference. But as time and experience have shown, Botulinum toxin is not just an alternate treatment; it also has some other indications in which surgery is not a smart choice. Although there are few randomised controlled trials, Botulinum toxin appears to work similarly to surgery for certain motility issues. Botulinum toxin produces a "chemodenervation" effect, inhibits the release of acetylcholine, and tampers with calcium metabolism. The paralytic effect lasts for two months after injection into an EOM, with the maximal effect occurring in five to seven days. BTXA's overall weakening impact lasts for six to nine months. It is anticipated that the antagonist will experience a relative contraction when under the influence of Botulinum toxin.
Although Botulinum toxin has a short-term impact on extraocular muscles (EOM), it may lead to a long-term reduction in deviation. Potential explanations for this long-lasting effect could include changes in the number of sarcomeres during its effect, immunohistochemical modifications, and central adaptive mechanisms that show up as better binocularity.
The primary goal of this study is to examine the efficacy and outcomes of botulinum toxin intramuscular injection therapy in the treatment of pediatric or adult strabismus, instead of performing surgery in these patients.
Our plan to use the Botulinum toxin in various doses by injecting it into the overacting extraocular musces in strabismus patients, especially pediatric, but also adult cases, to use it as an alternative for strabismus surgery. For children, it will be administered under sedation or general anesthesia and in adults, under topical anesthesia under sterile aseptic techniques. The preoperative and postoperative measurements of the type of strabismus, patterns, deviation, and post-operative results will be studied both in the short and long-term.
Study Oversight
Has Oversight DMC:
True
Is a FDA Regulated Drug?:
False
Is a FDA Regulated Device?:
False
Is an Unapproved Device?:
None
Is a PPSD?:
None
Is a US Export?:
False
Is an FDA AA801 Violation?:
Secondary ID Infos
| Secondary ID | Type | Domain | Link | View |
|---|---|---|---|---|
| 1004/RC/FFH/RWP | OTHER_GRANT | Fauji Foundation Hospital, Rwp | View |