Clinical Trial Details
— Status: Not yet recruiting
Administrative data
| NCT number |
NCT06152302 |
| Other study ID # |
APHP231293 |
| Secondary ID |
2022-A01419-34 |
| Status |
Not yet recruiting |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
May 2024 |
| Est. completion date |
July 2025 |
Study information
| Verified date |
January 2024 |
| Source |
Assistance Publique - Hôpitaux de Paris |
| Contact |
Susana Quijano-Roy, MD, PhD |
| Phone |
+ 33 1 47 10 78 90 |
| Email |
susana.quijano-roy[@]aphp.fr |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
Spinal muscular atrophy (SMA) is a genetic neurodegenerative disease impacting spinal cord
motor neurons, leading to motor and respiratory issues and, ultimately, death. With emerging
therapies, a need arises to enhance motor function assessment in severely hypotonic infants
(SMA type 1) as traditional scales on examination tables lack completeness due to gravity's
influence.
The study team has developed a "bath test" to observe infants' motor skills in water,
eliminating gravity's effects. This test aims to detect subtle movements using inertial
sensors, potentially revealing more active motor neurons in aquatic conditions. It aids in
identifying infants with motor improvement potential, even if they show limited mobility
outside water, and tracks disease progression and therapy responses.
Presently, pediatric neurologists in France use parent-provided bathing videos for
evaluations, but these lack standardization and precision. The study aims to establish a
standardized evaluation protocol with quantifiable data.
The study's key objective is to evaluate severely hypotonic SMA infants using inertial
sensors, including accelerometers, gyrometers, and magnetometers. The study will conduct
"dry" and "water" assessments using a specially designed bathtub. This method's goal is to
quantify water-based movements accurately.
Simultaneously, the study seeks to establish semi-quantitative evaluation criteria to create
a clinical assessment scale for infant motor function in bathtubs. This scale will aid
doctors in therapeutic decisions. The study will not influence the treatment or therapeutic
decisions made for the children being tested.
Collected data from "dry" and "water" conditions will be statistically analyzed and compared
to reference motor assessment scales (e.g., CHOP INTEND and HINE) and electromyography
(CMAP-EMG) results, commonly used in diagnosis and monitoring. Blurred video recordings will
assist in protocol monitoring and sensor data analysis.
Description:
This is a multicenter research project coordinated by the Child Neuromuscular Unit at Raymond
Poincaré Hospital. Additionally, two other pediatric neurology departments, part of the
national neuromuscular network FILNEMUS (https://www.filnemus.fr/), will participate in the
study: Necker Children's Hospital and Armand Trousseau Hospital.
The study's population will include all infants diagnosed with spinal muscular atrophy (SMA),
specifically SMA type 1, who have onset before 6 months of age and have been evaluated by the
French Therapeutic Commission. Participation in the study will be contingent on parental or
guardian consent during follow-up visits.
Spinal muscular atrophy is a genetic neurodegenerative condition that affects spinal motor
neurons, causing motor and respiratory paralysis and ultimately leading to death. As
groundbreaking therapies emerge, there's an increasing need to refine the methods used to
assess motor function, especially in infants with severe hypotonia due to SMA type 1.
Traditional reference scales used on examination tables are limited in their accuracy because
of gravitational effects. Consequently, there's growing interest in evaluating these
children's motor skills in water to detect movements unburdened by gravity. Pediatric
neurologists in France (SFNP) have already acknowledged the potential value of parental video
recordings during infant baths. However, the lack of standardization in recording conditions,
coupled with the subjective nature of video interpretations, underscores the necessity for a
more standardized and quantifiable approach. Herein lies the application of our proposed
evaluation utilizing inertial sensors.
Utilizing inertial sensors to detect subtle movements can highlight still-active yet
minimally functional motor neurons. Such detection can be pivotal in identifying children
who, despite severe motor skill limitations in traditional settings, still possess
developmental potential. Our study seeks to leverage these sensors-equipped with
accelerometers, gyroscopes, and magnetometers-to carry out evaluations both in ''dry''
conditions and ''water'' conditions, using a specially designed, secure bathtub.
The study aims to validate the relevance of quantifying movements in aquatic settings using
inertial sensors, in order to assess motor function in very hypotonic children. Additionally,
this study will contribute to the development of a semi-quantitative clinical evaluation grid
for assessing infant motor function in water, assisting physicians in making more informed
therapeutic decisions for these children. Data obtained from measurements with inertial
sensors in both environments ("dry" and "water") will be correlated with scores from
validated motor scales (CHOP INTEND; HINE-2) and the clinical characteristics of the patients
(e.g., age, disease duration, SMA type, SMN2 copies, severity, CMAPs [EMG]). Anamnestic,
clinical and inertial data will be anonymized.
The equipment required for the protocol comprises an examination table, a bath, a support for
the head and back (https://www.neut.fr/fr/), 8 CE-validated Xsens DOT© inertial sensors, a
dedicated research smartphone with the Xsens DOT© application for data export, a camera
mounted on a pole connected to an acquisition tablet. The study will utilize a fixed PC
computer with secure access, located in a dedicated research room within the Pediatric
Neurology and Intensive Care Unit at Raymond Poincaré Hospital.
Video recording throughout the evaluation will be carried out from an overhead perspective,
capturing all four limbs in the frame and ensuring that the child occupies approximately 50%
of the camera's field of vision. To comply with privacy regulations (MR-001), the videos will
obscure any identifying features, such as faces or other body parts of the patients. These
videos will serve as a reference for controlling and validating the data collected by the
inertial sensors.
The study's outputs will include inertial data from 8 inertial sensors placed on the arms
(2), forearms (2), thighs (2), and legs (2). Our motor evaluation process is split into two
distinct phases, totaling 6 minutes: a "dry" phase affected by gravity, and a "water" phase
where gravity's effects are mitigated. The surrounding time is allocated for essential tasks
such as positioning the child, fitting the sensors, and ensuring the infant's comfort
throughout the process. Notably, our study doesn't seek to alter the standard care or
therapeutic decisions for the participants.
The measurements will follow a specific process:
- "Dry" phase: This involves evaluating limb movements under the constraints of gravity.
The child is placed in a supine position on the examination table set horizontally (0°).
To minimize signal artifacts, physical contact with the child should be avoided. If the
child's behavior is unfavorable (e.g., crying), the measurement is paused and resumed
once the child's condition stabilizes. Spontaneous or induced movements are collected
for 2 minutes, with the entire duration filmed for monitoring the inertial sensor data.
- Intermediate phase: The diaper is removed, and the child is positioned in a support
inclined at 20°, then transferred to the bathtub. This transition should be made in a
reassuring manner for the child, respecting their pace of adaptation.
- "Water" phase: This phase involves evaluating limb movements without gravity
constraints. Spontaneous or induced movements are collected for 4 minutes, with the
entire duration filmed for monitoring the inertial sensor data. Measurements may also be
paused and resumed based on the child's behavior.
The processes of sensor installation and sensor removal are accompanied by sensorimotor
stimulation.
