免费获得国外相关药品,最快 1 个工作日回馈药物信息
Sickle Cell Disease, Hemechip
| Condition or disease | Intervention/treatment | Phase |
|---|---|---|
| Sickle Cell Disease | Device: HemeChip | Not Applicable |
Sickle cell disease (SCD) is a group of inherited disorders of haemoglobin (Hb) synthesis, first described in the medical literature by James Herrick in 1910. Each year about 300,000 infants are born with SCD, including more than 200,000 cases in subSaharan Africa alone. In Nigeria alone, there are over 150,000 of these children born annually and it is estimated that between 50-90% of these children die before their fifth birthday. Overall, in the region, 6% of all childhood mortality in children less than 5 years of age is due to SCD complications and infections. Vaso occlusive crisis and anemia are serious complications of SCD, with infection often being the major cause of hospitalizations, crisis and death. SCD is caused by a point mutation in the sixth codon of the beta globin chain that produces normal Hb (HbA). This substitution of hydrophilic glutamic acid with hydrophobic valine produces sickle Hb (HbS), which is abnormally polymerized at low oxygen conditions causing sickling. Abnormal polymerization of HbS affects red cell membrane properties, shape, and density, and subsequent critical changes in inflammatory cell and endothelial cell function.
The clinical consequences of SCD include painful crises, widespread organ damage, and early mortality. Current standard practices for diagnosing SCD are high performance liquid chromatography (HPLC) and bench-top Hb electrophoresis. These two approaches, however, require trained personnel and state-of-the-art facilities, both of which may be lacking in many parts of sub-Saharan Africa where the disease is most prevalent.
These laboratory methods also carry significant costs which may be unaffordable for most patients. HemeChip diagnostic system offers an original and innovative solution, leveraging a novel engineering approach, to point of care (POC) diagnosis of SCD. HemeChip separates haemoglobin protein types in a miniscule volume of blood (1μL) on a piece of cellulose acetate paper that is housed in a micro-engineered chip with a controlled environment and electric field. Differences in Hb mobilities allow separation to occur within the cellulose acetate paper. A micro-engineered design and multiple layer lamination approach are utilized in fabricating the HemeChip. The design allows rapid manual assembly and results are available within a few minutes of performing the test.
HemeChip can also integrate with a mobile user interface (e.g. IPhone, IPod), which shows the test result quantitatively and objectively on the screen. HemeChip can be used by anyone after a short (30 minute) training, eliminating the need for highly skilled personnel.
| Study Type : | Interventional (Clinical Trial) |
| Estimated Enrollment : | 5000 participants |
| Allocation: | N/A |
| Intervention Model: | Single Group Assignment |
| Masking: | None (Open Label) |
| Primary Purpose: | Diagnostic |
| Official Title: | Validation of a Point-of-care Screening Tool for Children With Sickle Cell Disease |
| Actual Study Start Date : | July 11, 2017 |
| Estimated Primary Completion Date : | May 30, 2021 |
| Estimated Study Completion Date : | May 30, 2022 |
- Validation of the HemeChip technology as a novel, point-of-care (POC) platform for screening SCD. [ Time Frame: 30 minutes ]The results obtained using the HemeChip will be compared to High Performance Liquid Chromatography (HPLC), and the sensitivity and specificity of the HemeChip will be determined.
| Tracking Information | |||||||||
|---|---|---|---|---|---|---|---|---|---|
| First Submitted Date ICMJE | May 1, 2019 | ||||||||
| First Posted Date ICMJE | May 14, 2019 | ||||||||
| Last Update Posted Date | May 14, 2019 | ||||||||
| Actual Study Start Date ICMJE | July 11, 2017 | ||||||||
| Estimated Primary Completion Date | May 30, 2021 (Final data collection date for primary outcome measure) | ||||||||
| Current Primary Outcome Measures ICMJE |
Validation of the HemeChip technology as a novel, point-of-care (POC) platform for screening SCD. [ Time Frame: 30 minutes ] The results obtained using the HemeChip will be compared to High Performance Liquid Chromatography (HPLC), and the sensitivity and specificity of the HemeChip will be determined.
|
||||||||
| Original Primary Outcome Measures ICMJE | Same as current | ||||||||
| Change History | No Changes Posted | ||||||||
| Current Secondary Outcome Measures ICMJE | Not Provided | ||||||||
| Original Secondary Outcome Measures ICMJE | Not Provided | ||||||||
| Current Other Pre-specified Outcome Measures | Not Provided | ||||||||
| Original Other Pre-specified Outcome Measures | Not Provided | ||||||||
| Descriptive Information | |||||||||
| Brief Title ICMJE | Sickle Cell Disease, Hemechip | ||||||||
| Official Title ICMJE | Validation of a Point-of-care Screening Tool for Children With Sickle Cell Disease | ||||||||
| Brief Summary | Sickle cell disease is very common in Nigeria. Early diagnosis is important to prevent or reduce serious complications from the disease and to enable children stay healthy. To this end, the investigators would like to test a new, simple and quick device called the HemeChip to determine if it can detect whether or not someone has sickle cell disease. The investigators will compare the results obtained with the HemeChip with a standard method of diagnosing sickle cell disease known as Isoelectric focusing (IEF) or High Performance Liquid Chromatography (HPLC).If the investigators show that the new device can differentiate between children who have sickle cell disease and those who don't as successfully as the IEF or HPLC, they estimate a sharp increase in the use of this device in many countries especially in Africa due to its lower cost | ||||||||
| Detailed Description |
Sickle cell disease (SCD) is a group of inherited disorders of haemoglobin (Hb) synthesis, first described in the medical literature by James Herrick in 1910. Each year about 300,000 infants are born with SCD, including more than 200,000 cases in subSaharan Africa alone. In Nigeria alone, there are over 150,000 of these children born annually and it is estimated that between 50-90% of these children die before their fifth birthday. Overall, in the region, 6% of all childhood mortality in children less than 5 years of age is due to SCD complications and infections. Vaso occlusive crisis and anemia are serious complications of SCD, with infection often being the major cause of hospitalizations, crisis and death. SCD is caused by a point mutation in the sixth codon of the beta globin chain that produces normal Hb (HbA). This substitution of hydrophilic glutamic acid with hydrophobic valine produces sickle Hb (HbS), which is abnormally polymerized at low oxygen conditions causing sickling. Abnormal polymerization of HbS affects red cell membrane properties, shape, and density, and subsequent critical changes in inflammatory cell and endothelial cell function. The clinical consequences of SCD include painful crises, widespread organ damage, and early mortality. Current standard practices for diagnosing SCD are high performance liquid chromatography (HPLC) and bench-top Hb electrophoresis. These two approaches, however, require trained personnel and state-of-the-art facilities, both of which may be lacking in many parts of sub-Saharan Africa where the disease is most prevalent. These laboratory methods also carry significant costs which may be unaffordable for most patients. HemeChip diagnostic system offers an original and innovative solution, leveraging a novel engineering approach, to point of care (POC) diagnosis of SCD. HemeChip separates haemoglobin protein types in a miniscule volume of blood (1μL) on a piece of cellulose acetate paper that is housed in a micro-engineered chip with a controlled environment and electric field. Differences in Hb mobilities allow separation to occur within the cellulose acetate paper. A micro-engineered design and multiple layer lamination approach are utilized in fabricating the HemeChip. The design allows rapid manual assembly and results are available within a few minutes of performing the test. HemeChip can also integrate with a mobile user interface (e.g. IPhone, IPod), which shows the test result quantitatively and objectively on the screen. HemeChip can be used by anyone after a short (30 minute) training, eliminating the need for highly skilled personnel. |
||||||||
| Study Type ICMJE | Interventional | ||||||||
| Study Phase ICMJE | Not Applicable | ||||||||
| Study Design ICMJE | Allocation: N/A Intervention Model: Single Group Assignment Masking: None (Open Label) Primary Purpose: Diagnostic |
||||||||
| Condition ICMJE | Sickle Cell Disease | ||||||||
| Intervention ICMJE | Device: HemeChip
The basis of HemeChip technology lies in Hb electrophoresis, in which Hb types C, A2, S, F, and A0 have net negative charges in an alkaline solution. Differences in Hb mobilities allow separation to occur within the sieving medium, cellulose acetate paper. HemeChip technology is a low-cost, point-of-care translation of the electrophoresis method that has been well established, readily accepted by clinicians, and widely applied in SCD diagnosis for well over 40 years. HemeChip offers a $2 screening test for SCD (and other Hb disorders), which takes 10 minutes to run. It is mobile and easy-to-use; it can be performed by anyone after a short (30 minute) training.
|
||||||||
| Study Arms ICMJE | Not Provided | ||||||||
| Publications * | Not Provided | ||||||||
|
* Includes publications given by the data provider as well as publications identified by ClinicalTrials.gov Identifier (NCT Number) in Medline. |
|||||||||
| Recruitment Information | |||||||||
| Recruitment Status ICMJE | Recruiting | ||||||||
| Estimated Enrollment ICMJE |
5000 | ||||||||
| Original Estimated Enrollment ICMJE | Same as current | ||||||||
| Estimated Study Completion Date ICMJE | May 30, 2022 | ||||||||
| Estimated Primary Completion Date | May 30, 2021 (Final data collection date for primary outcome measure) | ||||||||
| Eligibility Criteria ICMJE |
Inclusion Criteria:
Exclusion Criteria:
|
||||||||
| Sex/Gender ICMJE |
|
||||||||
| Ages ICMJE | 6 Weeks to 60 Months (Child) | ||||||||
| Accepts Healthy Volunteers ICMJE | Yes | ||||||||
| Contacts ICMJE |
|
||||||||
| Listed Location Countries ICMJE | Nigeria, United States | ||||||||
| Removed Location Countries | |||||||||
| Administrative Information | |||||||||
| NCT Number ICMJE | NCT03948516 | ||||||||
| Other Study ID Numbers ICMJE | 04-17-15 | ||||||||
| Has Data Monitoring Committee | Not Provided | ||||||||
| U.S. FDA-regulated Product |
|
||||||||
| IPD Sharing Statement ICMJE | Not Provided | ||||||||
| Responsible Party | Jane Little, University Hospitals Cleveland Medical Center | ||||||||
| Study Sponsor ICMJE | University Hospitals Cleveland Medical Center | ||||||||
| Collaborators ICMJE |
|
||||||||
| Investigators ICMJE | Not Provided | ||||||||
| PRS Account | University Hospitals Cleveland Medical Center | ||||||||
| Verification Date | May 2019 | ||||||||
|
ICMJE Data element required by the International Committee of Medical Journal Editors and the World Health Organization ICTRP |
|||||||||
