This document provides guidance from the FDA to encourage the evaluation of sex-specific data in medical device clinical studies. It aims to improve the quality of data on how devices perform in both sexes by recommending appropriate enrollment of women and men in studies. The guidance outlines recommendations for study design, conduct, analysis and reporting of data to better understand potential differences in device safety or effectiveness between sexes. This includes considering sex during study planning, pre-specifying sex-specific statistical analysis, and reporting enrollment demographics and outcomes by sex. The goal is to provide more useful information to patients, doctors and researchers on device performance in both female and male populations.
The document discusses informed consent regulations for research using leftover human biospecimens. It argues that moving to a broad consent standard could undermine public trust by prioritizing medical discovery over patient rights and privacy. Broad consent forms may confuse patients and fail to prevent unforeseen future uses of their genetic data. The regulations do not sufficiently prevent re-identification of specimens. Amendments are needed to clarify allowed re-identification circumstances and require prior written authorization. Separating informed consent for treatment from broad consent for unspecified future research allows patients to proceed with procedures without implied consent to downstream uses of their specimens.
Final FDA guidance on Medical Devices and Risk AnalysisDavid Sweigert
This document provides guidance for assessing benefits and risks when evaluating applications for investigational device exemptions (IDEs). It aims to clarify the factors considered by the FDA when making IDE approval decisions. The guidance emphasizes that effective risk management, including risk mitigation measures, can allow for a favorable benefit-risk determination. It also notes that earlier stages of device development are associated with greater uncertainty, but that uncertainty can be offset by risk controls. The guidance seeks to facilitate a balanced, comprehensive decision-making approach that considers clinical, nonclinical and patient perspectives.
The document discusses determining quality indicators for health information. Interviews with clinicians identified 21 quality criteria they use to evaluate health information. The criteria fall into objective and subjective categories. A prototype was developed to detect the criteria within a health record standard and model the results as quality indicators that could be presented to clinicians. The goal is to help clinicians safely rely on health information by highlighting important quality criteria.
FDA GUIDANCE: Safety Data Collection For Late Stage Premarket And Postapprovalcrr99999
This draft guidance discusses targeted safety data collection in late-stage clinical trials and post-approval studies. It recommends that selective collection of certain safety data may be appropriate when a drug's safety profile is well-established from previous studies. Targeted collection could include limiting collection of non-serious adverse events, routine lab monitoring, or concomitant medication history, or collecting data less frequently. The guidance provides examples of when targeted collection may be suitable, such as post-approval studies or late-phase pre-approval trials, to reduce burden while maintaining safety oversight. Comprehensive collection is still generally needed for original marketing applications or drugs with differences in intended use.
Report of the Expert Committee for the Selection and Inclusion of Medicines i...Alexandra Guta
The Expert Committee reviewed applications for 8 medicines used to treat noncommunicable diseases and prevent transplant rejection. They evaluated evidence on effectiveness, safety and cost compared to current treatment options. The Committee recommended including 6 medicines in the PAHO Strategic Fund list and not including 2 applications based on available evidence and alternatives.
Clinical Trial Registries & Databases: An UpdateMichael Swit
This document summarizes an educational conference presentation about clinical trial registries and databases. It defines key terms like clinical trial registries and results databases. It outlines the evolution of demands for more transparency including laws passed in 2000 requiring registration of certain trials. Major registries discussed include ClinicalTrials.gov, the WHO's ICTRP platform, and PhRMA's ClinicalStudyResults.org. Challenges of registries discussed include protecting competitive information and determining what data to publish. Future developments could include laws requiring disclosure of results.
Worldwide comprehensive study of guideline on clinical trialRGPV BHOPAL
The document provides information on various aspects of clinical trials including:
- The different phases of clinical trials from Phase 0 to Phase V
- Key elements of a clinical trial protocol such as objectives, design, and methodology
- Regulatory requirements for conducting clinical trials including compliance with ICH GCP guidelines
- Common recruitment strategies and important documents required for clinical trial authorization applications such as the clinical trial protocol, investigator brochure, and informed consent forms.
The document discusses standardizing clinical case report forms (CRFs) through the creation of a library of standardized CRF modules. It describes the process undertaken by a working group to analyze, harmonize and approve an initial CRF module on demography. The working group analyzed existing CRFs, agreed on core data elements, and obtained community input to create a standardized demography module. Subsequent modules on other topics will follow the same process.
The document discusses informed consent regulations for research using leftover human biospecimens. It argues that moving to a broad consent standard could undermine public trust by prioritizing medical discovery over patient rights and privacy. Broad consent forms may confuse patients and fail to prevent unforeseen future uses of their genetic data. The regulations do not sufficiently prevent re-identification of specimens. Amendments are needed to clarify allowed re-identification circumstances and require prior written authorization. Separating informed consent for treatment from broad consent for unspecified future research allows patients to proceed with procedures without implied consent to downstream uses of their specimens.
Final FDA guidance on Medical Devices and Risk AnalysisDavid Sweigert
This document provides guidance for assessing benefits and risks when evaluating applications for investigational device exemptions (IDEs). It aims to clarify the factors considered by the FDA when making IDE approval decisions. The guidance emphasizes that effective risk management, including risk mitigation measures, can allow for a favorable benefit-risk determination. It also notes that earlier stages of device development are associated with greater uncertainty, but that uncertainty can be offset by risk controls. The guidance seeks to facilitate a balanced, comprehensive decision-making approach that considers clinical, nonclinical and patient perspectives.
The document discusses determining quality indicators for health information. Interviews with clinicians identified 21 quality criteria they use to evaluate health information. The criteria fall into objective and subjective categories. A prototype was developed to detect the criteria within a health record standard and model the results as quality indicators that could be presented to clinicians. The goal is to help clinicians safely rely on health information by highlighting important quality criteria.
FDA GUIDANCE: Safety Data Collection For Late Stage Premarket And Postapprovalcrr99999
This draft guidance discusses targeted safety data collection in late-stage clinical trials and post-approval studies. It recommends that selective collection of certain safety data may be appropriate when a drug's safety profile is well-established from previous studies. Targeted collection could include limiting collection of non-serious adverse events, routine lab monitoring, or concomitant medication history, or collecting data less frequently. The guidance provides examples of when targeted collection may be suitable, such as post-approval studies or late-phase pre-approval trials, to reduce burden while maintaining safety oversight. Comprehensive collection is still generally needed for original marketing applications or drugs with differences in intended use.
Report of the Expert Committee for the Selection and Inclusion of Medicines i...Alexandra Guta
The Expert Committee reviewed applications for 8 medicines used to treat noncommunicable diseases and prevent transplant rejection. They evaluated evidence on effectiveness, safety and cost compared to current treatment options. The Committee recommended including 6 medicines in the PAHO Strategic Fund list and not including 2 applications based on available evidence and alternatives.
Clinical Trial Registries & Databases: An UpdateMichael Swit
This document summarizes an educational conference presentation about clinical trial registries and databases. It defines key terms like clinical trial registries and results databases. It outlines the evolution of demands for more transparency including laws passed in 2000 requiring registration of certain trials. Major registries discussed include ClinicalTrials.gov, the WHO's ICTRP platform, and PhRMA's ClinicalStudyResults.org. Challenges of registries discussed include protecting competitive information and determining what data to publish. Future developments could include laws requiring disclosure of results.
Worldwide comprehensive study of guideline on clinical trialRGPV BHOPAL
The document provides information on various aspects of clinical trials including:
- The different phases of clinical trials from Phase 0 to Phase V
- Key elements of a clinical trial protocol such as objectives, design, and methodology
- Regulatory requirements for conducting clinical trials including compliance with ICH GCP guidelines
- Common recruitment strategies and important documents required for clinical trial authorization applications such as the clinical trial protocol, investigator brochure, and informed consent forms.
The document discusses standardizing clinical case report forms (CRFs) through the creation of a library of standardized CRF modules. It describes the process undertaken by a working group to analyze, harmonize and approve an initial CRF module on demography. The working group analyzed existing CRFs, agreed on core data elements, and obtained community input to create a standardized demography module. Subsequent modules on other topics will follow the same process.
This document discusses grounding and its importance in electrical systems. It explains that ground provides a path for fault currents, stabilizes electrical signals, and limits voltage rises from transients. A good ground connection is important for safety and proper system operation. It then discusses grounding in AC power systems, how homes in North America are supplied 240V split-phase power from utilities via three wires, and how the electrical service panel distributes this power to circuits while connecting all grounds to earth.
Grounding for BASIC ELECTRICAL ENGINEERINGshubham211
This document discusses grounding in telecommunications systems. It covers the reasons for grounding including safety and equipment protection, different types of grounding methods for electrical, lightning, RF and electrostatic purposes. It then describes the key components of a telecom grounding system including bonding conductors, main grounding busbars, bonding backbones and grounding busbars. Bonding helps eliminate static discharge and reduce interference. Recommended materials for grounding and bonding include stranded copper conductors, compression lugs, busbars, hardware and conducting compounds.
The document discusses the importance of earthing systems in electrical installations. An earthing system connects all metallic bodies of electrical equipment to the earth through a low resistance wire. This serves to protect humans from electric shock by providing an alternative path for fault currents. It also ensures exposed conductive parts do not reach dangerous potentials and maintains voltage stability. A good earthing system has low impedance to allow fault currents to quickly blow fuses and disconnect faulty circuits.
Furse earthing-and-lightning-protection-product-catalogue SAUDI ARABIA LTD.AKBAR TRADING
This document provides information about Mohd. Bin Ahmed Akbar Trading Est., including their contact information and details about the services they provide related to electrical, automation, and instrumentation projects in Jubail, Saudi Arabia. It also contains two identical sections with the company's contact information.
The document provides an introduction to electrical grounding practices for power systems. It discusses the primary goals of grounding for safety and protection. It also describes the different types of grounding systems used in industry, including ungrounded, solid ground, low resistance ground, and high resistance ground. Each system is characterized by its handling of faults, safety aspects, reliability and economics.
BS 2 Individual assignment brief question august 2016Est
The document provides guidelines for an individual assignment on building services. It states that students must attempt a building services problem question and write an essay on a specified topic. The essay must adhere to minimum and maximum word limits and include footnotes, a bibliography, and references. It must be submitted as a softcopy by the given deadline of October 12, 2016. Any deviations from the guidelines will result in penalties to the student's score. The topic requires students to critically analyze and discuss various ways that air conditioning systems can enhance green technology in line with Malaysia's National Green Technology Policy.
This document provides information about a smoke control system for Building Services Two (BLD60503). It was prepared by Tan Hee Chai and details the smoke control system for the building. The smoke control system aims to maintain a tenable environment for evacuation and firefighting in the event of a fire.
BAND IT CABLE TIE | AKBAR TRADING EST | mail@akbartrading.comAKBAR TRADING
This document provides a product catalogue for BAND-IT brand band clamping systems. It lists various band and buckle systems, ties, clamps, fittings and other products for industrial applications. The catalogue includes specifications, materials information, and application examples for the different clamping and fastening solutions.
Ventilation is necessary in confined spaces to provide fresh air for respiration, maintain oxygen levels and remove carbon dioxide, control moisture levels, remove heat, odors and contaminants, and provide a sense of freshness. The ideal indoor relative humidity range is 40-60% to prevent adverse effects for occupants and the building. Rate of air change is calculated by dividing the fresh air supply per hour by the total room volume.
Absolute humidity measures the amount of water vapor in the air regardless of temperature, while relative humidity measures water vapor relative to the air's temperature. Warm air can hold more moisture than cold air. Maintaining an indoor relative humidity of 40-60% is optimal for health and comfort, as too much or too little humidity can cause issues. A Zehnder Enthalpy Exchanger recovers both thermal and humidity energy from extracted stale air and transfers it to incoming fresh air, helping maintain comfortable moisture levels in the home.
Ventilation is the replacement of stale or noxious air with fresh air through mechanical systems or natural means. Natural ventilation relies on pressure differences to move air through buildings, while stack ventilation uses pressure differences created by height differences. Building regulations require habitable rooms to have permanent background ventilation and windows that open, while non-habitable rooms and rooms like kitchens and bathrooms require mechanical extract ventilation or passive stack systems. Mechanical ventilation systems include extract fan systems, supply systems, and combined extract and input systems. The ideal indoor relative humidity range is 40-45% to prevent adverse effects for occupants and buildings.
This document discusses factors that influence human thermal comfort in buildings, including temperature, humidity, air speed and quality. It describes that an internal temperature of 19-23°C, humidity of 40-60% RH, and air speed of 0.1-0.25 m/s are typically comfortable for humans. It also examines psychrometric charts and concepts such as operative temperature, predicted mean vote and percentage dissatisfied to evaluate thermal comfort conditions. Proper ventilation is also needed to dilute contaminants and maintain adequate oxygen levels for occupant health.
Ventilation design guidelines recommend air velocities between 0.15-0.50 m/s depending on activity level, with sedentary work around 0.15-0.30 m/s and more active work 0.30-0.50 m/s. Duct sizing can be estimated through calculations using air volume flow rate formulas and applying results to design charts showing air velocity, pressure reduction, and duct size. Common duct sizing methods include the equal velocity method where the same velocity is used throughout, the velocity reduction method where velocity decreases in branches, and the equal friction/constant pressure drop method where the same friction figure is applied to all sections.
This document discusses various HVAC systems and air conditioning methods for buildings. It describes 6 common air conditioning systems: single duct systems, multi-zone systems, dual duct systems, induction systems, variable air volume systems, and fan coil units. It also discusses chilled ceilings, ventilated ceilings, terminal water loop heat pumps, and variable refrigerant volume systems. The key aspects and functioning of each system are explained in detail with diagrams.
This document provides tutorial questions for a ventilation design class. It asks students to use three different duct sizing methods - equal velocity, velocity reduction, and equal friction - to calculate the duct and fan sizes for a ventilation system based on the air flow rate and selected air velocities. It also asks students to determine the appropriate air changes per hour for a recording studio.
This document provides information on HVAC systems and air conditioning. It discusses various types of air conditioning units like window units, portable units, and split units. It then describes centralized air conditioning systems and the components of an air conditioning system, including air intake, pre-heating, filtration, cooling and dehumidifying coils, and dehumidification and humidification equipment. It explains the thermal duty of air conditioning systems and the sequence of air treatment for both summer and winter conditions.
This document discusses HVAC systems and building services. It describes three common types of fans used in HVAC including centrifugal, axial, and mixed flow fans. It also provides details on refrigeration cycles, specifically vapor compression and absorption cycles. The vapor compression cycle uses a compressor, condenser, expansion valve, and evaporator to circulate a refrigerant between gas and liquid states to produce cooling. Absorption refrigeration replaces the compressor with a generator and absorber that use a refrigerant and carrier fluid combination like ammonia/water or water/lithium bromide.
The document discusses ventilation systems for buildings. It describes the importance of ventilation for maintaining oxygen levels and removing impurities from indoor air. It provides recommendations for ventilation rates based on space volume and occupancy. Both natural ventilation utilizing wind and stack effects, and mechanical ventilation using fans and ductwork are covered. Key components of mechanical ventilation systems like fans, filters, ducts and diffusers are defined. Design principles for sizing ventilation ducts based on air flow rates are also presented.
The document discusses confined space entry regulations and procedures. It defines what constitutes a confined space and lists examples. It outlines potential hazards in confined spaces like oxygen deficiency, combustibles, and toxics. It discusses permit-required confined space entry procedures which include isolating, ventilating, conducting a tailgate meeting, testing the atmosphere, and entering with an attendant. It also covers non-permit confined space entry and responsibilities of entrants, attendants, supervisors, and contractors.
Lightning can strike up to 10 miles from a storm, averaging 2-3 miles between strikes. It travels at 100 million volts and over 100,000 amps, generating temperatures over 54,000 degrees Fahrenheit. To estimate how far away a lightning strike is, count the seconds between seeing the flash and hearing the thunder, as sound travels about 1 mile every 5 seconds. Proper lightning protection systems use air terminals to intercept strikes, conductors to guide current to ground, grounding rods, and surge protectors to mitigate damage.
This document provides guidance from the FDA on evaluating potential sex differences in medical device clinical studies. It recommends enrolling representative proportions of women and men in studies to improve understanding of device safety and effectiveness between sexes. Barriers to women's enrollment are discussed, such as safety concerns, under-diagnosis in women, and perceptions that women require more time and money. Strategies are provided to increase enrollment, like examining screening logs and considering childcare needs. The guidance advises analyzing data for sex differences and reporting results by sex. Considering sex-specific factors during study design is emphasized to ensure adequate evaluation of devices in both women and men.
This document discusses grounding and its importance in electrical systems. It explains that ground provides a path for fault currents, stabilizes electrical signals, and limits voltage rises from transients. A good ground connection is important for safety and proper system operation. It then discusses grounding in AC power systems, how homes in North America are supplied 240V split-phase power from utilities via three wires, and how the electrical service panel distributes this power to circuits while connecting all grounds to earth.
Grounding for BASIC ELECTRICAL ENGINEERINGshubham211
This document discusses grounding in telecommunications systems. It covers the reasons for grounding including safety and equipment protection, different types of grounding methods for electrical, lightning, RF and electrostatic purposes. It then describes the key components of a telecom grounding system including bonding conductors, main grounding busbars, bonding backbones and grounding busbars. Bonding helps eliminate static discharge and reduce interference. Recommended materials for grounding and bonding include stranded copper conductors, compression lugs, busbars, hardware and conducting compounds.
The document discusses the importance of earthing systems in electrical installations. An earthing system connects all metallic bodies of electrical equipment to the earth through a low resistance wire. This serves to protect humans from electric shock by providing an alternative path for fault currents. It also ensures exposed conductive parts do not reach dangerous potentials and maintains voltage stability. A good earthing system has low impedance to allow fault currents to quickly blow fuses and disconnect faulty circuits.
Furse earthing-and-lightning-protection-product-catalogue SAUDI ARABIA LTD.AKBAR TRADING
This document provides information about Mohd. Bin Ahmed Akbar Trading Est., including their contact information and details about the services they provide related to electrical, automation, and instrumentation projects in Jubail, Saudi Arabia. It also contains two identical sections with the company's contact information.
The document provides an introduction to electrical grounding practices for power systems. It discusses the primary goals of grounding for safety and protection. It also describes the different types of grounding systems used in industry, including ungrounded, solid ground, low resistance ground, and high resistance ground. Each system is characterized by its handling of faults, safety aspects, reliability and economics.
BS 2 Individual assignment brief question august 2016Est
The document provides guidelines for an individual assignment on building services. It states that students must attempt a building services problem question and write an essay on a specified topic. The essay must adhere to minimum and maximum word limits and include footnotes, a bibliography, and references. It must be submitted as a softcopy by the given deadline of October 12, 2016. Any deviations from the guidelines will result in penalties to the student's score. The topic requires students to critically analyze and discuss various ways that air conditioning systems can enhance green technology in line with Malaysia's National Green Technology Policy.
This document provides information about a smoke control system for Building Services Two (BLD60503). It was prepared by Tan Hee Chai and details the smoke control system for the building. The smoke control system aims to maintain a tenable environment for evacuation and firefighting in the event of a fire.
BAND IT CABLE TIE | AKBAR TRADING EST | mail@akbartrading.comAKBAR TRADING
This document provides a product catalogue for BAND-IT brand band clamping systems. It lists various band and buckle systems, ties, clamps, fittings and other products for industrial applications. The catalogue includes specifications, materials information, and application examples for the different clamping and fastening solutions.
Ventilation is necessary in confined spaces to provide fresh air for respiration, maintain oxygen levels and remove carbon dioxide, control moisture levels, remove heat, odors and contaminants, and provide a sense of freshness. The ideal indoor relative humidity range is 40-60% to prevent adverse effects for occupants and the building. Rate of air change is calculated by dividing the fresh air supply per hour by the total room volume.
Absolute humidity measures the amount of water vapor in the air regardless of temperature, while relative humidity measures water vapor relative to the air's temperature. Warm air can hold more moisture than cold air. Maintaining an indoor relative humidity of 40-60% is optimal for health and comfort, as too much or too little humidity can cause issues. A Zehnder Enthalpy Exchanger recovers both thermal and humidity energy from extracted stale air and transfers it to incoming fresh air, helping maintain comfortable moisture levels in the home.
Ventilation is the replacement of stale or noxious air with fresh air through mechanical systems or natural means. Natural ventilation relies on pressure differences to move air through buildings, while stack ventilation uses pressure differences created by height differences. Building regulations require habitable rooms to have permanent background ventilation and windows that open, while non-habitable rooms and rooms like kitchens and bathrooms require mechanical extract ventilation or passive stack systems. Mechanical ventilation systems include extract fan systems, supply systems, and combined extract and input systems. The ideal indoor relative humidity range is 40-45% to prevent adverse effects for occupants and buildings.
This document discusses factors that influence human thermal comfort in buildings, including temperature, humidity, air speed and quality. It describes that an internal temperature of 19-23°C, humidity of 40-60% RH, and air speed of 0.1-0.25 m/s are typically comfortable for humans. It also examines psychrometric charts and concepts such as operative temperature, predicted mean vote and percentage dissatisfied to evaluate thermal comfort conditions. Proper ventilation is also needed to dilute contaminants and maintain adequate oxygen levels for occupant health.
Ventilation design guidelines recommend air velocities between 0.15-0.50 m/s depending on activity level, with sedentary work around 0.15-0.30 m/s and more active work 0.30-0.50 m/s. Duct sizing can be estimated through calculations using air volume flow rate formulas and applying results to design charts showing air velocity, pressure reduction, and duct size. Common duct sizing methods include the equal velocity method where the same velocity is used throughout, the velocity reduction method where velocity decreases in branches, and the equal friction/constant pressure drop method where the same friction figure is applied to all sections.
This document discusses various HVAC systems and air conditioning methods for buildings. It describes 6 common air conditioning systems: single duct systems, multi-zone systems, dual duct systems, induction systems, variable air volume systems, and fan coil units. It also discusses chilled ceilings, ventilated ceilings, terminal water loop heat pumps, and variable refrigerant volume systems. The key aspects and functioning of each system are explained in detail with diagrams.
This document provides tutorial questions for a ventilation design class. It asks students to use three different duct sizing methods - equal velocity, velocity reduction, and equal friction - to calculate the duct and fan sizes for a ventilation system based on the air flow rate and selected air velocities. It also asks students to determine the appropriate air changes per hour for a recording studio.
This document provides information on HVAC systems and air conditioning. It discusses various types of air conditioning units like window units, portable units, and split units. It then describes centralized air conditioning systems and the components of an air conditioning system, including air intake, pre-heating, filtration, cooling and dehumidifying coils, and dehumidification and humidification equipment. It explains the thermal duty of air conditioning systems and the sequence of air treatment for both summer and winter conditions.
This document discusses HVAC systems and building services. It describes three common types of fans used in HVAC including centrifugal, axial, and mixed flow fans. It also provides details on refrigeration cycles, specifically vapor compression and absorption cycles. The vapor compression cycle uses a compressor, condenser, expansion valve, and evaporator to circulate a refrigerant between gas and liquid states to produce cooling. Absorption refrigeration replaces the compressor with a generator and absorber that use a refrigerant and carrier fluid combination like ammonia/water or water/lithium bromide.
The document discusses ventilation systems for buildings. It describes the importance of ventilation for maintaining oxygen levels and removing impurities from indoor air. It provides recommendations for ventilation rates based on space volume and occupancy. Both natural ventilation utilizing wind and stack effects, and mechanical ventilation using fans and ductwork are covered. Key components of mechanical ventilation systems like fans, filters, ducts and diffusers are defined. Design principles for sizing ventilation ducts based on air flow rates are also presented.
The document discusses confined space entry regulations and procedures. It defines what constitutes a confined space and lists examples. It outlines potential hazards in confined spaces like oxygen deficiency, combustibles, and toxics. It discusses permit-required confined space entry procedures which include isolating, ventilating, conducting a tailgate meeting, testing the atmosphere, and entering with an attendant. It also covers non-permit confined space entry and responsibilities of entrants, attendants, supervisors, and contractors.
Lightning can strike up to 10 miles from a storm, averaging 2-3 miles between strikes. It travels at 100 million volts and over 100,000 amps, generating temperatures over 54,000 degrees Fahrenheit. To estimate how far away a lightning strike is, count the seconds between seeing the flash and hearing the thunder, as sound travels about 1 mile every 5 seconds. Proper lightning protection systems use air terminals to intercept strikes, conductors to guide current to ground, grounding rods, and surge protectors to mitigate damage.
This document provides guidance from the FDA on evaluating potential sex differences in medical device clinical studies. It recommends enrolling representative proportions of women and men in studies to improve understanding of device safety and effectiveness between sexes. Barriers to women's enrollment are discussed, such as safety concerns, under-diagnosis in women, and perceptions that women require more time and money. Strategies are provided to increase enrollment, like examining screening logs and considering childcare needs. The guidance advises analyzing data for sex differences and reporting results by sex. Considering sex-specific factors during study design is emphasized to ensure adequate evaluation of devices in both women and men.
FDA GUIDANCE: Oversight Of Clinical Investigations Risk Based Approach To Mon...crr99999
This draft FDA guidance provides recommendations for using a risk-based approach to monitoring clinical investigations. It encourages sponsors to focus monitoring on critical data and processes, and to use centralized monitoring where appropriate in addition to on-site monitoring. The guidance aims to enhance human subject protection and data quality in clinical trials by making it clear that sponsors have flexibility in designing monitoring strategies.
Dr Dev Kambhampati | Postmarket management of cybersecurity in medical devicesDr Dev Kambhampati
This document provides guidance for industry and FDA staff on postmarket management of cybersecurity in medical devices. It establishes a risk-based framework for assessing when cybersecurity vulnerability corrections require FDA reporting. For most "cybersecurity routine updates and patches", manufacturers are not required to notify FDA in advance. However, for vulnerabilities that pose an uncontrolled risk to patient safety, manufacturers must notify FDA. The guidance recommends evaluating exploitability, impact on device performance, and severity of potential patient harm to assess risk level. It encourages proactive risk management and information sharing.
Guidance for Industry Patient-Reported Outcome Measures: Use in Medical Produ...CRF Health
This guidance describes how the Food and Drug Administration (FDA) reviews and evaluates existing, modified, or newly created patient-reported outcome (PRO) instruments used to support claims in approved medical product labeling.2 A PRO instrument (i.e., a questionnaire plus the information and documentation that support its use) is a means to capture PRO data used to measure treatment benefit or risk in medical product clinical trials. This guidance does not address the use of PRO instruments for purposes beyond evaluation of claims made about a medical product in labeling. This guidance also does not address disease-specific issues. Guidance on clinical trial endpoints for specific diseases can be found on various FDA Web sites.3
By explicitly addressing the review issues identified in this guidance, sponsors can increase the efficiency of their discussions with the FDA during the medical product development process, streamline the FDA’s review of PRO instrument adequacy and resultant PRO data collected during a clinical trial, and provide optimal information about the patient perspective for use in making conclusions about treatment effect at the time of medical product approval. PRO instrument development is an iterative process and we recognize there is no single correct way to develop a PRO instrument. Different strategies and methods can be used to address FDA review issues.
This guidance from the FDA provides recommendations for using a selective approach to safety data collection in late-stage premarket and postapproval clinical investigations. It advises that for common, non-serious side effects that are already well-characterized, collecting extensive additional data in large trials may not meaningfully contribute new safety information. The guidance discusses situations where more limited safety data collection may be appropriate and emphasizes the need to balance eliminating unnecessary data collection with obtaining sufficient information to characterize a drug's safety profile. It also notes sponsors should consult with the relevant FDA division to determine if a selective approach is suitable for a specific investigation.
The document summarizes FDA regulation of medical devices in the United States. It discusses that many medical devices must undergo premarket review by the FDA to be legally marketed. Devices are classified based on risk, and moderate and high-risk devices must receive FDA clearance or approval prior to marketing, usually via the 510(k) or premarket approval (PMA) processes. Concerns have been raised about FDA's device review processes and oversight of marketed devices based on reports of device problems causing injuries.
The document presents clinical practice guidelines from The Endocrine Society for the diagnosis of Cushing's syndrome. It provides recommendations on who should be tested, initial tests to use, subsequent evaluation of abnormal results, and special populations. The objective is to develop guidelines to aid physicians. A task force reviewed evidence and developed consensus recommendations, graded based on evidence quality and strength. They recommend testing patients with features of Cushing's, investigating abnormal initial test results with a second test, and determining the cause of Cushing's for those with two abnormal tests.
FDA 1997 Points to Consider for Monoclonal Antibodiesisoasp
This document provides guidance for the manufacture and testing of monoclonal antibody products intended for human use. It covers topics such as cell line establishment, production and purification processes, quality control testing, preclinical studies, and clinical trial considerations. The guidance is intended to facilitate development of monoclonal antibodies, especially for serious or life-threatening diseases, while ensuring product safety. Feedback is sought on this guidance to improve its usefulness.
Challenges and Opportunities Around Integration of Clinical Trials DataCitiusTech
Conducting a Clinical Trial is a complex process, consisting of activities such as protocol preparation, site selection, approval of various authorities, meticulous collection and management of data, analysis and reporting of the data collected
Each activity is benefited from the development of point applications which ease the process of data collection, reporting and decision making. The recent advancements in mobile technologies and connectivity has enabled the generation and exchange of a lot more data than previously anticipated. However, the lack of interoperability and proper planning to leverage this data, still acts as a roadblock in allowing organizations truly harness their data assets. This document will help life sciences IT professionals and decision makers understand challenges and opportunities around clinical data integration
Digital Scholar Webinar: Clinicaltrials.gov Registration and Reporting DocumentsSC CTSI at USC and CHLA
The document provides information about clinicaltrials.gov registration and reporting requirements. It discusses that the U.S. Department of Health and Human Services, National Institutes of Health (NIH) requires registration of applicable clinical trials on ClinicalTrials.gov. Registration must occur within 21 days of enrolling the first participant, and results must be reported within 12 months of trial completion. The document reviews the registration process, what types of trials must be registered, responsibilities of the responsible party, and penalties for noncompliance.
This document summarizes key findings from a report on hospitalizations and emergency department visits due to opioid poisoning in Canada between 2007-2015. It finds that opioid poisonings result in over 13 hospitalizations per day across Canada, and 7 emergency department visits per day in Ontario and 3 in Alberta. Hospitalization and emergency department visit rates increased over 30% and 50% respectively during this period. Seniors aged 65 and older consistently had the highest hospitalization rates, reaching 20 per 100,000 population. Accidental poisonings accounted for nearly half of hospitalizations overall and over half among seniors. The report aims to improve understanding of opioid-related harms to inform initiatives addressing this public health issue.
Use of Genetic Databases to Advance Diagnostic Test DevelopmentEMMAIntl
In December 2018, the U.S. Food and Drug Administration formally recognized a public database that contains information about genes, genetic variants, and their relationship to disease. This blog discusses the motivation for creating such public databases and the implications for developers of genetic tests...
The Role of Real-World Evidence in Supporting a Product's Value StoryCovance
Randomized clinical trials (RCTs) are the gold standard for gaining regulatory approval for marketing authorization for medical products. RCTs typically measure short-term efficacy and safety of a product compared to placebo in a fairly homogeneous population and under ideal, controlled conditions. In contrast, the real world consists of a heterogeneous population in which patient care is much less controlled and thus, more complex. Treatment decisions made in this setting are predicated on a wider array of co-morbid conditions, competing medications, physician preference and risk of adverse events than those observed in RCT populations. Evidence generated from real-world settings reflects this complexity, complementing evidence derived from rigorously controlled RCTs.
The United States has always been and remains to be the leading place
for the conduct of clinical trials. According to Clinicaltrials.gov, the largest
clinical trials registry, 32% of registered clinical trials were conducted in
the U.S. as of May 2022 (1). Factors such as the availability of qualified
healthcare professionals, high-quality infrastructure and facilities,
cutting-edge research, an efficient regulatory system, and a high
standard of ethics and participant protection make the U.S. the leading
country for clinical trials.
Clinical trials follow extensive preclinical research to test the safety and
efficacy of a new drug, medical device, or biological in humans. They are
usually divided into three phases: phases I, II, and III which are designed
to ascertain safety, pharmacokinetics, efficacy, dosage, and adverse
events. Figure 1 shows the typical route from discovery and preclinical
studies to the post-marketing phase (phase IV).Clinical trials represent the longest and most expensive step in bringing
drugs to the market and have the highest attrition rate, only 10% of drugs
that enter phase I trials are granted marketing approval. Therefore,
clinical trials should be conducted by experts that are
well-versed with all the regulations and guidelines in a particular region to
boost the chances of drug approval.
The United States Food and Drug Administration (US FDA) is the
regulatory body that approves and oversees the conduct of clinical trials
for drugs, medical devices, and biologicals that are intended to be
marketed in the U.S and is touted to have the most stringent standards
for drug approval. The primary role of the FDA is to protect public health
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Evaluation of sex specific data in medical device clinical studies
1. Evaluation of Sex-Specific Data in
Medical Device Clinical Studies
Guidance for Industry and Food and
Drug Administration Staff
Document issued on August 22, 2014.
The draft of this document was issued on December 19, 2011
For questions regarding this document, contact CDRH at 301-796-5900 or Kathryn O’Callaghan
(kathryn.ocallaghan@fda.hhs.gov); for Office of Device Evaluation specific questions, Jismi
Johnson (jismi.johnson@fda.hhs.gov); for Statistics specific questions, Lilly Yue
(lilly.yue@fda.hhs.gov); for Office of In Vitro Diagnostics and Radiological Health specific
questions, Robert Becker (robertl.becker@fda.hhs.gov); or for Epidemiology specific questions,
Nilsa Loyo-Berrios (nilsa.loyo-berrios@fda.hhs.gov).
For questions about this document regarding CBER regulated devices, contact the Office of
Communication, Outreach and Development (OCOD) by calling 1-800-835-4709 or240-402-7800.
U.S. Department of Health and Human Services
Food and Drug Administration
Center for Devices and Radiological Health
Center for Biologics Evaluation and Research
2. Contains Nonbinding Recommendations
Preface
Public Comment
You may submit written comments and suggestions at any time for Agency consideration to
the Division of Dockets Management, Food and Drug Administration, 5630 Fishers Lane,
rm. 1061, (HFA-305), Rockville, MD, 20852. Submit electronic comments to
http://www.regulations.gov. Identify all comments with the docket number FDA-2011-D-
0817. Comments may not be acted upon by the Agency until the document is next revised or
updated.
Additional Copies
Additional copies are available from the Internet. You may also send an e-mail request to
CDRH-Guidance@fda.hhs.gov to receive a copy of the guidance. Please use the document
number 1727 to identify the guidance you are requesting.
Additional copies of this guidance document are also available from the Center for Biologics
Evaluation and Research (CBER) by written request, Office of Communication, Outreach and
Development 10903 New Hampshire Ave., Silver Spring, MD 20993, Bldg. 71, Rm. 3128,
1-800-835-4709 or240-402-7800, by email, ocod@fda.hhs.gov, or from the Internet at
http://www.fda.gov/BiologicsBloodVaccines/GuidanceComplianceRegulatoryInformation/d
e fault.htm.
3. Contains Nonbinding Recommendations
TABLE OF CONTENTS
I. INTRODUCTION .....................................................................................................................................1
II. SCOPE........................................................................................................................................................2
III. BACKGROUND........................................................................................................................................2
A. WHY CONSIDER SEX DIFFERENCES? ..........................................................................................................3
B. PARTICIPATION OF WOMEN IN CLINICAL STUDIES ....................................................................................5
1. Lack of Available Data for Women ...................................................................................................5
2. Barriers to Enrollment of Women .....................................................................................................7
IV. RECOMMENDATIONS FOR ACHIEVING APPROPRIATE ENROLLMENT.............................9
A. CONSIDERATION OF POTENTIAL SEX DIFFERENCES ..................................................................................9
1. For New or Ongoing Studies (IDE study design/early enrollment stage)........................................9
2. For Completed Studies (marketing application stage)....................................................................10
3. For Postmarket Studies (PAS or 522 PS stage)...............................................................................10
B. STUDY DESIGN AND CONDUCT ...............................................................................................................10
1. For New or Ongoing Studies (IDE study design/early enrollment stage)......................................10
2. For Completed Studies (marketing application stage)....................................................................11
3. For Postmarket Studies (PAS or 522 PS stage)...............................................................................12
V. CONSIDERING SEX IN STUDY DESIGN AND DATA INTERPRETATION ..............................14
A. STATISTICAL CONCEPTS FOR ASSESSING HETEROGENEITY ACROSS SEX GROUPS..................................14
1. For New or Ongoing Studies (IDE study design/early enrollment stage)......................................15
2. For Completed Studies (marketing application stage)....................................................................16
3. For Postmarket Studies (PAS or 522 PS stage)...............................................................................16
B. RECOMMENDATIONS FOR SEX-SPECIFIC STATISTICAL ELEMENTS IN STUDY DESIGN .............................16
When Sex Group Differences are Anticipated ............................................................................................16
Pre-specifying Assessment of Heterogeneity Across Sex Groups in Study Design.....................................17
Additional Considerations for Particular Study Design Types ..................................................................18
Special Considerations for Diagnostic Devices..........................................................................................18
C. RECOMMENDATIONS FOR ANALYSIS AND INTERPRETATION OF SEX-SPECIFIC DATA IN COMPLETED
STUDIES............................................................................................................................................................19
Sex-Specific Analysis ..................................................................................................................................19
Additional Considerations for Data Analysis in Particular Study Design Types.......................................19
D. INTERPRETATION OF SEX-SPECIFIC DATA...............................................................................................21
VI. RECOMMENDATIONS FOR REPORTING SEX-SPECIFIC INFORMATION IN
APPLICATIONS AND PUBLIC DOCUMENTS ...........................................................................................21
A. ENROLLMENT DEMOGRAPHICS, BASELINE CHARACTERISTICS & CO-MORBIDITIES ...............................21
1. For New or Ongoing Studies (IDE study design/early enrollment stage)......................................22
2. For Completed Studies (marketing application stage)....................................................................22
3. For Postmarket Studies (PAS or 522 PS stage)...............................................................................22
B. SEX-SPECIFIC OUTCOMES (SAFETY OR EFFECTIVENESS) ........................................................................22
1. For Completed Studies (marketing application stage)....................................................................23
2. For Postmarket Studies (PAS or 522 PS stage)...............................................................................23
APPENDIX 1 – DECISION FRAMEWORK..................................................................................................24
RECOMMENDATIONS FOR SEX-SPECIFIC STATISTICAL DESIGN....................................................24
4. Contains Nonbinding Recommendations
RECOMMENDATIONS FOR SEX-SPECIFIC STATISTICAL ANALYSES FOR COMPLETED STUDIES
- ONE –ARM STUDIES..................................................................................................................................25
RECOMMENDATIONS FOR SEX-SPECIFIC STATISTICAL ANALYSES FOR COMPLETED STUDIES
- COMPARATIVE STUDIES.........................................................................................................................26
5. Contains Nonbinding Recommendations
1
Evaluation of Sex-Specific Data in
Medical Device Clinical Studies
Guidance for Industry and Food and Drug
Administration Staff
This guidance represents the Food and Drug Administration's (FDA's) current thinking
on this topic. It does not create or confer any rights for or on any person and does not
operate to bind FDA or the public. You can use an alternative approach if the approach
satisfies the requirements of the applicable statutes and regulations. If you want to discuss
an alternative approach, contact the FDA staff responsible for implementing this
guidance. If you cannot identify the appropriate FDA staff, call the appropriate number
listed on the title page of this guidance.
I. Introduction
This document provides guidance on the study and evaluation of sex-specific data in
medical device clinical studies. The purpose of this guidance is to outline the FDA’s
expectations regarding sex-specific patient enrollment, data analysis, and reporting of
study information. The primary intent is to improve the quality and consistency of
available data regarding the performance of medical devices in both sexes by
encouraging appropriate enrollment by sex in clinical studies of devices, and that data
from such studies is appropriately analyzed by sex. This information can be of benefit to
patients and their medical providers, as well as clinical researchers and others.
The specific objectives of this guidance are to: 1) encourage the consideration of sex and
associated covariates (e.g., body size, plaque morphology, etc.) during the study design
stage; 2) provide recommendations for study design and conduct to encourage
appropriate enrollment of each sex (e.g., in proportions generally representative of the
demographics of disease distribution, if appropriate); 3) outline recommended sex-
specific statistical analyses of study data with a framework for considering sex-specific
data when interpreting overall study outcomes; and 4) specify FDA’s expectations for
reporting sex-specific information in summaries and labeling for approved or cleared
medical devices.
FDA’s guidance documents, including this guidance, do not establish legally enforceable
responsibilities. Instead, guidances describe the Agency’s current thinking on a topic and
should be viewed only as recommendations, unless specific regulatory or statutory
requirements are cited. The use of the word should in Agency guidances means that
something is suggested or recommended, but not required.
6. Contains Nonbinding Recommendations
2
II. Scope
This guidance is intended for devices that require clinical information in support of a
marketing submission, whether a premarket notification (510(k)), premarket approval (PMA)
application, Evaluation of Automatic Class III Designation (de novo request), or
humanitarian device exemption (HDE) application. The recommendations contained herein
also apply to post-approval study (PAS) submissions and postmarket surveillance (PS)
studies conducted in accordance with Section 522 of the Food, Drug and Cosmetic Act,
where noted.
Sex1
is not the only demographic variable that may affect device performance. While this
guidance focuses on the impact of sex, some of its recommendations may also be used to
promote study enrollment and data analysis adequately accounting for other demographic
variables, such as age, race, and ethnicity. 2
1
Public comment indicated interest in addressing unique considerations regarding the participation of lesbian,
gay, bisexual, transgender, and queer (LGBTQ), intersex, and gender non-conforming (GNC) individuals in
clinical studies. The analyses of sex-specific data related to these groups fall outside the scope of this guidance;
other forums, such as the Health of Women Program, could be used to explore these issues.
<http://www.fda.gov/MedicalDevices/NewsEvents/WorkshopsConferences/ucm346073.htm>
2
Consult the Agency-wide guidance for industry Collection of Race and Ethnicity Data in Clinical Trials,
which was issued September 2005. FDA guidance documents are available at
http://www.fda.gov/ForIndustry/FDABasicsforIndustry/ucm234622.htm.
The impact of demographic variables may apply more to certain types of products or diseases
than others. For example, certain OB/GYN and urology devices may be intended for use in
single-sex populations, so studies of these devices would not be expected to address the
potential for sex differences in outcome. Additionally, some in vitro diagnostic (IVD) device
clinical studies are conducted on de-identified left over specimens so it may not be possible to
obtain demographic information, including sex. As a result, evaluation of sex-specific data
would not be possible in these cases.
FDA recommends the use of this guidance document as a supplement to other FDA guidance,
in particular, any relevant device-specific guidance. Consultation with the FDA primary
reviewing division is advised.
III. Background
Certain elements described in this guidance have been emphasized in Agency regulations
and/or policy in the past. Over recent decades the Agency’s views, as well as those of
the medical community in general, have evolved regarding women in clinical studies.
Prior to developing the policy set forth in this guidance, FDA publicly sought input from a
variety of experts and stakeholders regarding the study and evaluation of women in clinical
studies for medical devices. On June 2, 2008, various government agencies, physician
professional societies, and patient advocacy groups participated in a public workshop to
7. Contains Nonbinding Recommendations
3
discuss ways to overcome barriers to understanding the impact of sex differences on clinical
outcomes, with a focus on clinical study conduct and statistical analysis. On December 9,
2008, FDA’s Center for Devices and Radiological Health (CDRH) and an industry trade
association co-hosted a second public meeting to facilitate discussion in anticipation of
issuance of FDA guidance on this subject.3
This guidance document reflects the
recommendations generated in these and other public fora and in subsequent internal Agency
discussions. It is intended to provide guidance on the design and conduct of clinical studies
to improve sex-specific information about the safety and effectiveness of approved new
medical devices.
3
http://www.regulations.gov/#!documentDetail;D=FDA-2008-N-0038-0089
4
Institute of Medicine, Committee on Understanding the Biology of Sex and Gender Differences. Exploring
the Biological Contributions to Human Health: Does Sex Matter? National Academy of Sciences, 2001.
5
Sex refers to the classification of living things, generally as male or female according to their reproductive
organs and functions assigned by chromosomal complement.
6
Gender refers to a person’s self representation as male or female, or how that person is responded to by social
institutions based on the individual’s gender presentation. Gender is rooted in biology, and shaped by
environment and experience.
The terms sex and gender are often used interchangeably in the scientific literature and
popular press. However, according to a 2001 consensus report from the Institute of
Medicine, the terms have distinct definitions which should be used consistently to describe
research results.4
The differences of greatest interest to FDA are those associated with
biological factors (sex5
); however most medical device studies rely on patient self-reported
values (gender6
). For the purposes of this guidance document we use the term sex, with the
understanding that for most medical device studies gender is used as a surrogate for sex.
This guidance focuses on addressing potential differences in study design, conduct,
outcomes, and interpretation that should be considered to ensure sex-specific issues are
adequately addressed in clinical studies.
A. Why consider sex differences?
Certain medical products elicit different responses in women compared to men.
Differences may be attributable to intrinsic factors (e.g., genetics, hormones, body size,
sex-specific physiology), extrinsic factors (e.g., diet, sociocultural issues, environment)
or interactions between these factors. For example, there may be medical conditions that
are unique to a certain sex, ethnic or racial group which should be considered in study
recruitment and in reporting of results. Additionally, differences in patient-reported
outcomes between certain groups, for example how men and women report pain
differently, may suggest a sex difference in outcome, but they may not necessarily be
related to the medical device itself.
Covariates associated with female sex (e.g., size, age, co-morbidities, past pregnancies)
may be responsible for certain differences in safety, effectiveness, or design attributes
such as failure mode. Fluctuations associated with hormonal changes (e.g., onset of
puberty, menstrual cycle, menopause, oral contraceptive or hormone replacement therapy
use) may interact with clinical outcomes. Additionally, the menstrual cycle is associated
8. Contains Nonbinding Recommendations
4
with hormonally-mediated differences in metabolism or changes in fluid balance which
could lead to intra-subject variability.
Following are examples where sex differences affect FDA’s regulatory considerations:
1. Ventricular Assist Devices (VADs) provide mechanical circulatory support for
patients with heart failure. One study of a next-generation VAD showed that
in subjects treated with the investigational device, female sex or covariates
associated with sex (body surface area, BSA) were found to be correlated with
a higher rate of stroke in women as compared to men (18% vs. 6%). There
were also trends toward increased rates of bleeding and infection in women
compared to men. There did not appear to be differences in primary
effectiveness outcome of survival (to cardiac transplantation or 180 days of
support while being listed as status United Network for Organ Sharing
(UNOS) 1A/1B for transplant). The strength of these conclusions is somewhat
limited by the sample size (150 men and 44 women). The FDA Advisory
Committee recommended that a post-approval study be conducted which
would include adequate collection of data regarding both sex and body surface
area to determine if differences exist in device performance. (Thoratec
HeartMate II, Summary of Safety and Effectiveness:
http://www.accessdata.fda.gov/cdrh_docs/pdf6/P060040b.pdf)
2. Cardiac Resynchronization Therapy Defibrillators (CRT-D) provide two
functions. As an implantable cardioverter defibrillator (ICD) it senses
dangerous abnormal heart rhythms and then delivers a shock to stop the
abnormal rhythm, allowing the normal rhythm to resume. As cardiac
resynchronization therapy, it generates small electrical impulses to coordinate
the beating of the left and right ventricles so that they work together more
efficiently to pump blood throughout the body. In one study, the benefit of
CRT-D therapy over ICD alone (benefit defined as reduction in the composite
endpoint of all-cause mortality or first heart failure event) was observed to be
greater in women than men (77% versus 42%). Left Bundle Branch Block
(LBBB) is a marker of an electrical conduction disorder in the heart and has
been associated with a greater benefit in patients receiving CRT; the
proportion of subjects with LBBB in this study was significantly greater in
women than men (87% versus 65%). These findings are considered
exploratory since the sex-specific analysis was post hoc. There did not appear
to be differences in primary safety outcome of system-related complication-
free survival within 91 days post implant. The FDA Advisory Committee
recommended that two post-approval studies be conducted that would include
adequate collection of data regarding the effects of the therapy in patients
fulfilling the approved indication.
3. Hip joint deterioration can lead to pain, stiffness or difficulty walking. When
these symptoms do not respond to conservative treatment, such as physical
9. Contains Nonbinding Recommendations
5
therapy, patients may be advised to undergo total hip replacement (THR) or
hip resurfacing. As part of this treatment, patients may receive a “metal-on-
metal” (MoM) hip implant in which the “ball and socket” of the device are
both made from metal.7
In June 2012, the Orthopaedic and Rehabilitation
Devices Advisory Panel met to discuss the clinical performance of MoM hip
implants as well as associated adverse events, including early device failure
and the need for revision surgery.8
The THR and hip resurfacing studies that
identified revision rates by sex show that the revision rate appeared higher
among women 3-5 years post implant in most studies. Sex-specific revision
rates in THR studies ranged between 2.7% to 19.8% for women and 0 and
14.6% for men. Sex-specific revision rates in the resurfacing studies ranged
between 0 and 27.6% for women and 1.4% and 8.97% for men.9
Differences
in sex-specific revision rates and the basis for these differences were a
recurring concern throughout the panel discussion. From this information,
FDA recommendations for orthopedic surgeons include that women may be at
risk for increased device wear and/or adverse local tissue reactions and should
be followed more closely.
7
Metal-on-Metal Hip Implants.
<http://www.fda.gov/MedicalDevices/ProductsandMedicalProcedures/ImplantsandProsthetics/MetalonMetalHi
pImplants/default.htm> Page last updated 1/17/2013
8
2012 Meeting Materials of the Orthopaedic and Rehabilitation Devices Panel.
<http://www.fda.gov/AdvisoryCommittees/CommitteesMeetingMaterials/MedicalDevices/MedicalDevicesAdv
isoryCommittee/OrthopaedicandRehabilitationDevicesPanel/ucm309184.htm> Page last updated 10/18/2012.
9
FDA Executive Summary Memorandum. Metal-on-Metal Hip Implant Systems. June 27-28, 2012.
<http://www.fda.gov/downloads/AdvisoryCommittees/CommitteesMeetingMaterials/MedicalDevices/Medical
DevicesAdvisoryCommittee/OrthopaedicandRehabilitationDevicesPanel/UCM309302.pdf>
10
U.S. Department of Health, Education, and Welfare, "General Considerations for the Clinical Evaluation of
Drugs, HEW (FDA) 77-3040" (Government Printing Office, Washington, September 1977).
11
Women's health. Report of the Public Health Service Task Force on Women's Health Issues. Public Health
Rep. 1985 Jan–Feb; 100(1): 73–106.
B. Participation of Women in Clinical Studies
Historically, women have been under-represented in or excluded from many clinical
studies. This has led to a lack of information available for women and their physicians
regarding the risks and benefits of many medical treatments and diagnostic procedures.
1. Lack of Available Data for Women
Concerns about representation of women in U.S. clinical trials initially surfaced
in the drug context. In the mid-1970s, legislation and subsequent regulations and
guidelines conveyed the recommendations of FDA and many in the medical and
scientific community that women “of child-bearing potential” be excluded from
drug studies to protect the fetus from exposure to unknown drugs.10
However, it
soon became apparent that this policy contributed to “compromis[ing] the quality
of health information available to women as well as the health care they
receive.”11
10. Contains Nonbinding Recommendations
6
The Government Accountability Office (GAO) audited clinical study information
submitted to FDA in support of drug marketing applications, and concluded in a
1992 report that women were significantly underrepresented, and sex-specific
data analysis was performed in less than 50% of drug studies.12
The following
year, the FDA issued a “Guideline for the Study and Evaluation of Gender
Differences in the Clinical Evaluation of Drugs” which encouraged participation
of women in early phase (dosing) studies, required data collection on sex
differences, and encouraged consideration of the effect of menstrual cycle and
potential interaction with oral contraception or hormone replacement therapy.13
In 1994, CDRH discussed addressing the possibility of “gender bias” in
submissions and review documentation for new medical devices.14
12
United States General Accounting Office. Women’s Health. FDA Needs to Ensure More Study of Gender
Differences in Prescription Drug Testing. (http://archive.gao.gov/d35t11/147861.pdf).
13
http://www.fda.gov/downloads/RegulatoryInformation/Guidances/UCM126835.pdf
14
CDRH ODE Annual Report FY1994.
15
United States General Accounting Office. Women’s Health. Women Sufficiently Represented in New Drug
Testing, but FDA Oversight Needs Improvement. (http://www.gao.gov/new.items/d01754.pdf, ed,: 2001).
16
Evelyn B, Toigo T, Banks D, Pohl D, Gray K, Robins B, Ernat J. Women's Participation in Clinical Trials
and Gender-Related Labeling: A Review of New Molecular Entities Approved 1995-1999. June 2001.
(http://www.fda.gov/ForConsumers/ByAudience/ForPatientAdvocates/ParticipatinginClinicalTrials/ucm19778
8.htm.)
17
Kramer DB, Mallis E, Zuckerman BD, Zimmerman BA, Maisel WH. Premarket Clinical Evaluation of Novel
Cardiovascular Devices: Quality Analysis of Premarket Clinical Studies Submitted to the Food and Drug
Administration 2000–2007. Am J Therapeutics. 2009.
18
FDA Report. Collection, Analysis, and Availability of Demographic Subgroup Data for FDA-Approved
Medical Products. August 2013.
http://www.fda.gov/downloads/RegulatoryInformation/Legislation/FederalFoodDrugandCosmeticActFDCAct/
SignificantAmendmentstotheFDCAct/FDASIA/UCM365544.pdf
A 2001 report by the GAO on FDA-reviewed drug studies found that women
accounted for 52% of total study enrollees, but approximately 30% of the study
documents examined did not report outcomes by sex, and almost 40% did not report
enrollment demographics.15
Since then, the FDA Office of Special Health Issues
published a 2003 report which showed improvements in the inclusion of women and
sex-specific analysis and reporting in drug studies for most medical areas except
AIDS, oncology, and heart disease.16
In medical device studies, an evaluation of cardiovascular PMAs reported in 2009
showed pivotal studies that reported sex enrolled an average of 33.9% women.17
In a
2013 report to Congress responding to requirements in Section 907 of FDASIA
regarding demographic subgroup data in medical product clinical studies, FDA
showed that participation rates for women varied by device product area, a
phenomenon attributable to a number of factors that can influence interpretation and
clinical relevance of demographic information (e.g., intended population, disease
prevalence, etc.). Additionally, 88% of the PMA applications reviewed for the report
contained a sex subgroup analysis, and 63% of these applications contained
statements in the device labeling and/or FDA summary review on sex subgroup
analysis.18
11. Contains Nonbinding Recommendations
7
2. Barriers to Enrollment of Women
Women may be less likely to enroll in clinical studies. There are myriad suspected
reasons for the continued lower participation rates of women in clinical studies in
certain product areas. Some of the key reasons suggested at the June 2008 FDA
workshop include:
Lack of understanding about main obstacles to participation of women in
clinical research;
Fear of fetal consequences if a female participant becomes pregnant (e.g.,
effects of radiographic assessments or concomitant drug therapy);
Inclusion/exclusion criteria potentially not needed to define the study
population may unintentionally exclude women (e.g., upper age limit);
Lack of understanding about differences in disease etiology and
pathophysiology may lead to under-diagnosis and under-referral of women;
Investigator and sponsor avoidance of female patients due to the perception
that it takes more time and money to recruit them; and
Family responsibilities limiting women’s ability to commit time for study
follow-up.
In addition to the list above, in a 2009 report to Congress,19
FDA further identified
barriers to the participation of subsets of the general population and medically
underserved populations in the context of drug trials. This report included public
comments submitted in response to a Notice in the Federal Register (74 FR 1695)
seeking information on specific impediments to participation of certain groups in
clinical studies; what practices currently exist to increase participation in clinical
studies; and whether additional approaches are necessary to increase the participation
of certain subsets of the general population in clinical studies. The recommendations
and best practices submitted in response to the FR Notice, along with FDA’s
identification of particular areas of concern, are summarized in Part II of the 2009
report to Congress. Lower rates of participation by women in device clinical studies
may also be attributable in part to limitations of manufacturing certain medical
devices to accommodate anatomical differences between women and men; for
19
See Report to Congress; Food and Drug Administration Amendments Act (FDAAA) of 2007, Public Law
No. 110-85 Section 901 of the Federal Food, Drug, and Cosmetic Act; Direct-to-Consumer Advertising’s
Ability to Communicate to Subsets of the General Population; Barriers to the Participation of Population
Subsets in Clinical Drug Trials.
http://www.fda.gov/downloads/RegulatoryInformation/Legislation/FederalFoodDrugandCosmeticActFDCAct/
SignificantAmendmentstotheFDCAct/FoodandDrugAdministrationAmendmentsActof2007/FDAAAImplement
ationChart/UCM213016.pdf.
12. Contains Nonbinding Recommendations
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example, technology may not yet be developed to manufacture smaller sizes or
certain configurations of some devices which could increase use in women.
Where ongoing enrollment data demonstrate an underrepresentation of women
enrolling in the study, sponsors are encouraged to investigate the reason for lack of
enrollment and consider the approaches in Section IV.B.1. to enhance enrollment. It
may be informative to evaluate whether the demographic distribution varies at
different key time points (e.g., at screening, after evaluation of study
inclusion/exclusion criteria, after consent, and at various follow-up time points). For
example, if the proportion of women drops significantly after screening for
inclusion/exclusion criteria, this may suggest that the study criteria may need to be
examined to reduce inappropriate, unintentional exclusion of women. Similarly,
cutoffs excluding patients with smaller body surface area (BSA) may exclude large
proportions of female patients who may otherwise benefit from treatment. Removing
such exclusions (entirely or through parallel cohort studies) could improve the
participation rates of women in the overall study. Information regarding changes in
demographic distribution at key time points in study screening, enrollment, and
follow-up can provide insight into methods to substantially lower barriers to
enrollment of women, as well as other subgroups of study participants, (e.g.,
flexibility in follow-up visit scheduling with consideration of child care or elder care
services during appointments). Changes to a study protocol and informed consent
may be made based on demographic distribution information with appropriate
notification to and approval from the IRB and FDA, where necessary.
Sponsors may also wish to consider resources the National Institutes of Health
developed,20, 21, 22
or discussion with academic and contract research organizations,
and high-enrolling clinical study sites, in determining practices best suited to achieve
appropriate enrollment with respect to demographic groups, and to provide
investigator training about these techniques.
20
NIH Office of Research on Women’s Health has a number of publications available which provide advice on
inclusion criteria, an overview of key elements in recruitment and retention, and a number of practical
applications for conducting human subjects research, including ethical considerations.
http://orwh.od.nih.gov/research/inclusion/index.asp.
21
The National Institute of Mental Health developed a resource document (“Points to Consider about
Recruitment and Retention While Preparing a Clinical Research Study”), which outlines common issues that
can impact clinical recruitment and retention, and strategies to address these issues.
http://www.nimh.nih.gov/research-funding/grants/recruitment-points-to-consider-6-1-05.pdf.
22
The National Cancer Institute developed an online resource designed for practicing professionals to support
clinical trial accrual needs. The Web site is a repository for literature and other resources and serves as a
'community of practice' to encourage dialog and discussion. https://accrualnet.cancer.gov.
Some specific examples of strategies to increase inclusion are discussed in Section
IV.B below.
13. Contains Nonbinding Recommendations
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IV. Recommendations for Achieving Appropriate
Enrollment
It remains important that clinical trials include diverse populations which reflect the intended
population, whenever possible and appropriate. In general, to achieve an unbiased estimate
of treatment effect in the general population, sponsors should plan to enroll representative
proportions of women and men (e.g., consistent with disease prevalence). However, in cases
where disease science or prior clinical study results suggest treatment effect in only one sex,
sponsors may need to intentionally enroll sufficient numbers to support valid analysis (i.e., a
sample size sufficient for sex-specific claims).
Historically, many medical device clinical studies have not enrolled proportions of women
that reflect the underlying disease distribution in the affected population. This can be
problematic because the ability to detect differences in response to treatment is markedly
diminished if there is no or limited clinical experience with the product in the subgroup of
interest. This has contributed to a substantial lack of available data regarding the risks and
benefits of medical device use in women.
A. Consideration of Potential Sex Differences
To understand potential sex differences that may be relevant to the clinical evaluation of
your device, we recommend that you investigate whether sex differences may or may not
exist for the disease or condition which your device is intended to treat or diagnose in the
following areas:23
23
The intent is to provide context based on disease science. Sponsors may consider providing similar
information related to other demographic groups such as age, race, ethnicity, co-morbidities, etc.
sex-specific prevalence;
sex-specific diagnosis and treatment patterns;
identification of proportions of women included in past studies for the target
indication;
identification of any known clinically meaningful sex differences in outcomes
related to either safety or effectiveness
If information demonstrating sex differences is available, it should be included in your
study and submission documents as described in the following sections. FDA recognizes
that such information is limited in some device development programs (e.g., those based
on testing of de-identified non-annotated specimens).
1. For New or Ongoing Studies (IDE study design/early enrollment stage)
You should include the information described above as part of the risk analysis
section of your investigational plan (see 21 CFR 812.25(c)). We also recommend
that you summarize this information in your study protocol and investigator training
14. Contains Nonbinding Recommendations
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materials to explain the importance of enrolling appropriate proportions of women.
For studies which are already enrolling under an approved (or conditionally
approved) IDE where there is inadequate enrollment of women, FDA and the sponsor
should discuss an appropriate path to communicate this new information to
investigators without introducing bias to the study.
2. For Completed Studies (marketing application stage)
Where available background information or clinical study results suggest there are
clinically meaningful sex differences, you should include this information as part of
your marketing application in sections containing results of clinical investigations. A
summary of this information should also be included in your draft PMA Summary of
Safety and Effectiveness or 510(k) Summary, and in your labeling (see Section VI
below for more details).
3. For Postmarket Studies (PAS or 522 PS stage)
Where available background information or clinical study results suggest there are
clinically meaningful sex differences, you should include this information in interim
reports and in the results section of your final report. If warranted, you should also
submit revised labeling to include this information.
B. Study Design and Conduct
As discussed Section III.B., women have been historically under-represented in clinical
studies of medical devices; therefore, the approaches described below are aimed at
increasing enrollment of women in your study. However, in fields where men may be
under-represented (e.g., breast cancer diagnosis, bone density scans) we recommend that
you adapt these or other methods to increase enrollment of men if the intended
population also includes men. Some of these methods may also be adapted to increase
enrollment of other typically underrepresented groups, such as racial and ethnic
minorities.
1. For New or Ongoing Studies (IDE study design/early enrollment stage)
You should develop and describe your plan to prospectively enroll proportions of
each sex in your study which are appropriate based on the contextual information
provided in Section IV. A. (e.g., consistent with the sex-specific prevalence of the
disease or condition which your device is intended to treat or diagnose). To enhance
enrollment of women, the approaches described below may be considered, with
appropriate caution designed to avoid introducing bias or jeopardizing data validity.
a. Target investigational sites where recruitment of women can be more easily
facilitated (e.g., women’s clinics).
15. Contains Nonbinding Recommendations
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b. Consider alternative communication strategies (as used in the Women’s
Health Initiative study24
) for study recruitment, informed consent documents,
and patient materials.
24
J. Hays, et al. The Women’s Health Initiative Recruitment Methods and Results. Ann Epidemiol
2003;13:S18–S77.
25
CDRH Guidance on IDE Policies and Procedures (1998):
http://www.fda.gov/MedicalDevices/DeviceRegulationandGuidance/GuidanceDocuments/ucm080202.htm.
c. If women are likely to benefit from your device but may not meet certain
study enrollment criteria, consider revising the enrollment criteria, when
appropriate, or consider parallel cohorts for collecting data on device use in
women.
d. Responsibly enroll women of child-bearing age with appropriate risk
reduction to avoid pregnancy during clinical trial participation.
e. Include provisions to encourage certain target enrollment for women (e.g.,
maintain open enrollment for women until pre-specified proportion is
reached).
f. Investigate reasons for under-enrollment or non-enrollment of women or other
key demographic groups (e.g., periodically evaluate screening logs for all
patients who are screened but not ultimately enrolled in studies).
g. Plan focused efforts to enroll women under a continued access study.25
h. Consider factors that generally increase recruitment and retention such as
community or local health care practitioner involvement in recruiting or
referring patients, incentives or compensation (e.g., for transportation costs),
and presentation of the benefits of participating in the study (e.g., send a
newsletter to subjects to maintain interest).
i. Consider flexibility in follow-up visit scheduling with provision of child care
or elder care services during appointments or to allow various opportunities
that match subjects' schedules, which may include evenings and weekends.
j. For in vitro diagnostic tests and diagnostic devices, include samples from both
women and men at the cutoff selection and validation stages.
2. For Completed Studies (marketing application stage)
If available evidence suggests that there may be clinically meaningful sex differences
in outcomes (related to safety and/or effectiveness) with your device, results should
then be discussed within your marketing application and considered in the context of
available alternative treatments to determine whether additional data collection (for
men and/or women) are needed to address a clinically important question before the
16. Contains Nonbinding Recommendations
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device is marketed. Consideration should also be given to whether results support
market approval in one sex, with additional pre-market data collection in the other
sex; or whether market approval is supported for both sexes, with post-market studies
to gain further information regarding any observed sex differences. The FDA team
may recommend that you consider:
a. Planning focused efforts to enroll women or men under a continued access
study
b. Including provisions to encourage certain target enrollment for women or men
(e.g., maintain open enrollment for women until a pre-specified proportion is
reached).
3. For Postmarket Studies (PAS or 522 PS stage)
You should develop and describe your plan to enroll and retain proportions of women
and men in your study that are consistent with the sex-specific prevalence of the type
of disease or condition that your device is intended to treat or diagnose. For PAS
designed for continued follow-up of the pivotal study cohort, FDA may determine
that additional study of one sex is warranted if the pre-market study data suggest
there are clinically meaningful sex differences. To enhance enrollment of women or
men, we recommend that you undertake the following:
a. Consider whether outstanding questions warrant specific post-market
evaluation in female-only or male-only studies based, for example, on sex-
specific signals observed in pre-market clinical studies or known sex
differences in the underlying disease or the response to concomitant treatment
or therapies that may affect safety or effectiveness.
b. Target investigational sites where recruitment of needed populations can be
more easily facilitated (e.g., women’s clinics).
c. Consider alternative communication strategies (as used in the Women’s
Health Initiative study26
) for study recruitment, informed consent documents
and patient labeling.
26
J. Hays, et al. The Women’s Health Initiative Recruitment Methods and Results. Ann Epidemiol
2003;13:S18–S77.
d. Periodically evaluate screening logs to identify reasons for under-enrollment
of women or men or other key demographic groups.
e. Consider factors that increase recruitment such as community or local health
care practitioner involvement in recruiting or referring patients, incentives or
compensation (e.g., for transportation costs), and presentation of the benefits
of participating in the study (e.g., send a newsletter to subjects to stimulate
interest).
17. Contains Nonbinding Recommendations
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f. Consider flexibility in follow-up visit scheduling with provision of child care
or elder care services during appointments or to allow various opportunities
that match subjects' schedules, which may include evenings and weekends.
We also recommend that sponsors and clinical study investigators consider the
approaches described below, which can help avoid or minimize loss-to-follow up of
subjects (regardless of sex).
Sponsor Responsibilities
a. Develop a follow-up plan that details follow-up goals, frequency of contacts,
and number and type of contact for patients missing a follow-up visit.
b. Demonstrate interest in the subjects (e.g., send newsletter to subjects to
maintain interest).
c. Monitor follow-up rates closely so that follow-up problems can be identified
and addressed as soon as possible.
d. Report subject accountability data as part of the study report.
Investigator Responsibilities
a. Counsel subjects about the importance of returning to follow-up during
informed consent and follow-up visits.
b. Remind subjects of upcoming scheduled follow-up visits.
c. Attempt to locate/return patients who miss scheduled clinic visits.
d. Obtain proxy information to use when unable to contact a study subject.
e. Ask subjects who withdraw during the study to provide the reason for
withdrawal and ask them whether the investigator may contact them once
more at the end of the study follow-up to assess the experience with device
f. Demonstrate interest in the subjects (e.g., telephone follow-up after surgery,
particularly if the device is implantable).
18. Contains Nonbinding Recommendations
14
V. Considering Sex in Study Design and Data
Interpretation
Differences between men and women range from the obvious (e.g., sexual organs, body fat
distribution) to the less obvious (e.g., bone density, blood viscosity). Genetic sex can affect
all levels of biological organization (cell, organ, organ system, and organism), including
susceptibility to disease. Differences across the sexes in the incidence and severity of certain
diseases may be related to differences in exposures, routes of entry and processing of a
foreign agent, and cellular responses. In addition, differences in health and illness are
influenced by an individual’s experiences and interaction with the environment, which may
be affected by sex.27
Therefore, unless the investigational device is intended for use in only
one sex (e.g., pregnancy test, or PSA testing), it is important that the variation in data across
sex be considered in both study design and interpretation of study data.
27
Committee on Understanding the Biology of Sex and Gender Differences. Exploring the Biological
Contributions to Human Health: Does Sex Matter? Institute of Medicine, National Academies of Science.
2001.
A. Statistical Concepts for Assessing Heterogeneity Across Sex Groups
There may be a substantial difference in how a device performs in women versus men in
terms of safety or effectiveness. Thorough investigation of heterogeneity across sex groups,
especially for primary safety and effectiveness endpoints, should be conducted.
Heterogeneity here refers to a difference in outcome across sexes. Statistical hypothesis tests
can be performed to detect heterogeneity, and methods of statistical inference for estimating
its magnitude are also available.
When multiple treatment groups are considered, a form of heterogeneity is treatment by sex
interaction, which measures the magnitudes of differences in outcome across treatments in
one sex compared with the other. The concept of treatment by sex interaction applies to a
study endpoint (such as probability of survival, adverse event rate) involving the comparison
between two treatments. It is important to distinguish between qualitative versus quantitative
interactions. Qualitative treatment by sex interaction for a parameter refers to the situation
where one treatment is superior to the other in one sex, but not in the opposite sex.
Quantitative treatment by sex interaction refers to the situation where one treatment is
superior to the other in both sexes but by different amounts (See Figure 1 below).
19. Contains Nonbinding Recommendations
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Quantitative Interaction
0.00
0.10
0.20
0.30
0.40
0.50
0.60
0.70
0.80
male female
Control Treatment
Qualitative Interaction
0.00
0.10
0.20
0.30
0.40
0.50
0.60
0.70
0.80
male female
Control Treatment
Figure 1. Illustrations of quantitative (left graph) and qualitative (right graph) interactions.
Statistical hypothesis tests of treatment by sex interaction have been widely utilized to detect
treatment effect heterogeneity across sex. Most of the tests of interaction in common use
have as their null hypotheses the absence of treatment by sex interaction. As statistical tests,
their significance levels should be pre-specified in the investigational plan. Note, however,
that the power of such tests may be unspecified. Therefore, lack of statistical significance for
a test of treatment by sex interaction may not convincingly evidence the absence of clinically
relevant interaction. By the same token, moderate statistical significance may not
convincingly evidence the presence of clinically relevant interaction. While statistically
significant interactions will be investigated for their clinical meaningfulness, interactions
without associated statistical significance may also be examined for clinical reasons specific
to the design and endpoint.
For studies involving a single treatment with a single device (one-arm study), heterogeneity
across sex groups can be assessed only for that single treatment and device. The concept of
treatment by sex interaction has no direct applicability in such studies. To assess
heterogeneity, statistical hypothesis tests comparing two sex groups under the (single) study
treatment may be utilized, and in this specific context they are often subject to limitations
similar to those besetting the aforementioned statistical tests of treatment by sex interaction.
Other patient characteristics (e.g., body size, co-morbidities, age) correlated with sex
sometimes might explain apparent sex differences in clinical outcomes. If differences
between men and women are observed, FDA recommends that a sponsor investigate
potential explanation of the differences by other patient characteristics.
1. For New or Ongoing Studies (IDE study design/early enrollment stage)
The Statistical Analysis Plan (SAP) in the protocol should include pre-specified plans
for addressing the issues described in the sections below.
20. Contains Nonbinding Recommendations
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It remains important that clinical trials include diverse populations that reflect the
intended population, whenever possible and appropriate. In general, to achieve an
unbiased estimate of treatment effect in the general population, sponsors should
provide a strategy to enroll representative proportions of women and men (e.g.,
consistent with disease prevalence).
Sponsors should make an effort to identify in advance any key covariates that might
explain possible differences across sexes, to plan to collect data on these covariates,
and to pre-specify a modeling approach to investigate the extent to which these
covariates can explain the observed differences.
2. For Completed Studies (marketing application stage)
In general, all studies should report descriptive statistics for outcomes of interest by sex as
detailed in Section C below. After overall effectiveness and safety have been investigated,
the influence of sex on primary endpoints for both safety and effectiveness should be
assessed. If any clinically meaningful sex differences are suspected, either based on pre-
specified or exploratory post hoc analyses, sponsors should discuss with FDA to determine
whether additional data are needed to address any remaining sex-specific questions of safety
or effectiveness
3. For Postmarket Studies (PAS or 522 PS stage)
For PAS involving continuing data collection on PMA cohort patients, we recommend that
you conduct the analyses described in Section C below for all follow-up time points.
For PAS (or 522 PS studies) involving newly enrolled patients, you should include the
analyses described in Section C below as part of a pre-specified statistical analysis plan in
your protocol. Furthermore, if results from sex-specific analyses of pre-market data suggest
there may be a clinically meaningful difference in outcomes, you should consult with the
Division of Epidemiology to determine whether this should also be incorporated into the
study design and hypothesis for your PAS.
When exploring sex-related differences during analysis of data from a PAS or 522 PS study,
we recommend you address the issue of confounding by using multivariate analyses adjusted
for patient characteristics that may confound the relationship between sex and study
outcomes (e.g., smaller size, diabetes, etc.).
B. Recommendations for Sex-Specific Statistical Elements in Study Design
When Sex Group Differences are Anticipated
If, based on previous studies, literature, or disease science, important differences in
the benefit-risk profile of a medical device are anticipated between men and women,
clinical study design should take this into consideration.
21. Contains Nonbinding Recommendations
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For devices that are appropriate for both men and women, where background
information or previous clinical study results point to the potential existence of a
clinically meaningful difference by sex, the study may need to be powered to evaluate
treatment effect for both sex groups if the intended claim is for both sexes. In other
words, sponsors may need to intentionally enroll sufficient number of patients in each
sex group to allow valid analysis (i.e., a sample size sufficient for sex-specific
claims); a stratified study design with outcome analyses by sex may be needed.
A single study can be designed to support marketing approval for the combined
population of men and women or one sex only. A common key element of all such
study designs is successful control of Type 1 error rates at the desired levels, taking
into account the multiplicity due to the two ways to claim study success. Just as with
any study having a complex design, the sponsor is encouraged to talk to FDA early.
Although rarely done, it is possible to plan a study that simultaneously investigates
the overall treatment effect and the effect on only one subgroup such as women (or
men). This would be done if the claim were for the entire population or just one pre-
identified sex. One approach would be to allocate some fraction f of the overall Type
I error rate (alpha) to the investigation of the overall inferential procedure and the
rest to investigating the particular subgroup. In the hypothesis testing framework, the
study would then be successful if either the overall test were significant at level f
times alpha or the subgroup was effective at level (1-f) times alpha.
Studies may be designed to investigate overall treatment effect in the combined
population, and if positive, conduct pre-specified secondary analyses in one sex or
another.
Pre-specifying Assessment of Heterogeneity Across Sex Groups in Study Design
Unless a device to be studied is intended for use in only one sex (e.g., pregnancy test,
PSA testing), it is important that variability in data across sex groups and its
interpretation be considered in the study design even if no substantial sex difference
is expected at the design stage.
The statistical analysis plan should include a strategy for assessing heterogeneity
across sexes, since FDA recommends such an assessment as an integral part of
interpreting study results for every submission. In particular, the heterogeneity
assessment can serve as the basis for poolability conditions for studies with pre-
specified success criteria expressed in terms of data pooled across sex groups. Such
poolability conditions bear some resemblance to those commonly used for
determining whether data can appropriately be pooled for analysis across different
clinical sites. Poolability conditions may be specified as statistical hypothesis tests,
which, for studies involving the comparison of two treatments, would typically be
tests of treatment by sex interaction. The interaction tests should ideally be able to
detect interaction of relevant magnitude measured on pertinent parameters with a
reasonably high probability, and this goal should guide the choice of appropriate
significance level.
22. Contains Nonbinding Recommendations
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Additional Considerations for Particular Study Design Types
For one-arm studies:
o Sponsors should provide strategy for assessing heterogeneity across sex
groups. 28
The specific methodology could vary; if the methodology requires
any assumptions, the validity of these assumptions should be investigated.
o Sponsors may also consider sex-specific objective performance criteria (OPC)
or performance goals. It may be used for sex-specific claims. It is important
to control overall type 1 error rate to support any multiple claims based on
hypothesis testing.
For comparative studies:
o Sponsors should pre-specify interaction testing. The validity of any
assumptions should be investigated.
o Sponsors may consider powering for sex-specific claims when sex-subgroup
differences are anticipated. If seeking multiple claims based on hypothesis
testing, it is important to control overall type 1 error rate.
o If the control is non-randomized or historical and patient-level data exist, then
the interaction can be investigated in conjunction with a propensity score data
analysis.
o For randomized controlled trials, sponsors may consider sex as a stratification
variable in the randomization process if clinically meaningful sex difference is
anticipated.
28
This type of analysis is currently conducted for the purposes of determining whether data can appropriately
be pooled for analysis.
Special Considerations for Diagnostic Devices
For in vitro diagnostic assays, imaging devices, and diagnostic devices in which a cutoff is
used, sponsors should include data from both women and men both at the cutoff selection
and cutoff validation stages. An assay or device involves a cutoff whenever a continuous or
ordinal measurement is used to separate patients into two or more categories (for example,
diseased and non-diseased). Separate cutoffs for men and women should be used only when
there is reason to believe separate cutoffs are needed based on previous evidence or if the
data in the current clinical study provide evidence for different cutoffs. The use of separate
cutoffs may affect study design and sample size calculations. Analysis by sex of clinical
performance measures such as sensitivity, specificity, positive and negative likelihood ratios,
and positive and negative predictive values should be performed. Analysis of reference
intervals with regard to mean (median) values, standard deviation and percentiles should be
performed for men and women separately. Separate reference intervals for men and women
should be considered only if they will be clinically useful and when there is reason to believe
such intervals are needed based on previous evidence. For new measurands, if the
information necessary to decide these questions is not available, but the data of the reference
23. Contains Nonbinding Recommendations
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interval study indicate sex-specific differences, reference intervals should be presented for
men and women separately and for combined data. Situations may arise in which an assay or
device has high overall accuracy (e.g., very high sensitivity and specificity); when this
occurs, subgroup analysis may not be warranted.
C. Recommendations for Analysis and Interpretation of Sex-Specific Data
in Completed Studies
Sex-Specific Analysis
In general, all studies should report descriptive statistics for outcomes of interest, including
the estimate of variance or standard deviation (as applicable), by sex. At the primary follow-
up time-point, regardless of the potentially limited statistical power of these sex-specific
subgroup analyses, data should be examined for clinically meaningful sex differences in each
of the following:
o primary effectiveness endpoint(s);
o primary safety endpoint(s); and
o key secondary endpoints.
After overall effectiveness and safety have been investigated, the influence of sex on
primary endpoints for both safety and effectiveness (and in some cases for important
secondary endpoints as well) should be assessed.
It is important to carry out all analyses set forth in the Statistical Analysis Plan
(SAP). FDA expects sponsors to plan and conduct analyses to evaluate heterogeneity
by sex, including treatment by sex interaction when applicable, as described in
previous sections.
In some cases the test for treatment by sex interaction (or heterogeneity in general)
may have adequate power to detect only a very large interaction (or heterogeneity)
but may fail to detect a smaller yet clinically important interaction (or heterogeneity).
Such situations may arise when the number of patients in one or both of the sex
groups is small, in which case additional data from men or women (or both) may be
required. Observed heterogeneity could exist across sexes due to large variability
associated with small sample sizes; interpretation of clinical meaningfulness may be
premature in those cases. Consultation with FDA is recommended.
For recommendations on interpreting data, see Section D below.
Additional Considerations for Data Analysis in Particular Study Design Types
For one-arm studies:
24. Contains Nonbinding Recommendations
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o If overall treatment effect is neither statistically significant nor clinically
meaningful, subgroup analyses are not recommended. In such cases, analysis
likely raises questions about data to support marketing application.
o If no significant difference is observed across sexes, data may be poolable
across sex.
o If a significant difference is observed across sexes, it is important to explore
whether the difference remains significant after adjusting for other covariates.
If not, data may be poolable across sex.
o If difference remains significant after adjusting for other covariates, data may
not be poolable across sex. Additional data may be required to appropriately
evaluate the effect of sex on the study endpoints. In these cases, discussion
with FDA is advised.
For comparative studies:
o If overall treatment effect is not statistically significant and clinically
meaningful, subgroup analyses are not recommended. In such cases, analysis
likely raises questions about data to support marketing application.
o If there is evidence of an interaction of treatment by sex, it is important to
describe the nature of interaction (qualitative or quantitative) and assess the
clinical importance of the differences. In some cases, the interaction effect
could be statistically significant but not clinically meaningful, or clinically
meaningful but not statistically significant. In these cases, discussion with
FDA is advised.
o If no significant interaction effect between treatment and sex is observed for
the outcome of interest, data may be poolable across sex. However, the
decision about the validity of pooling the data should be based on the size of
the observed interaction effect as well as its clinical importance.
o If a treatment effect difference is noted across sexes, it is usually helpful to
perform additional analyses to investigate possible explanations for this
difference using variables such as body size (e.g., body mass index), bone
density or concomitant illness (e.g., diabetes). If significant interaction effect
between treatment and sex is observed, explore whether this remains
significant after adjusting for other covariates. If not, data may be poolable
across sex.
o If the interaction effect remains significant after adjusting for other covariates,
data may not be poolable across sex. Additional data may be required to
appropriately evaluate the effect of sex on the study endpoints. In these cases,
discussion with FDA is advised.
o If a significant treatment by sex interaction has been identified, it may be
helpful to investigate if there is a sex difference in treatment group only,
control group only, or both. Alternately, the interaction could be explored by
assessing whether there is a treatment difference in women only, men only, or
both.
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D. Interpretation of Sex-Specific Data
If any clinically meaningful sex differences are found, either based on pre-specified or
exploratory post hoc analyses, you should discuss with FDA whether additional data are
needed to address any remaining sex-specific questions.
If results of your analysis suggest that there is insufficient data to assess whether sex is
associated with clinically meaningful differences in outcome, FDA may determine that
clinical data from additional subjects in one or both sexes may be needed pre- or
post-market to address potential sex-specific questions related to safety or effectiveness.
Although expected to be rare, in cases where clinically meaningful differences between
the sexes are observed in safety or effectiveness, FDA may request additional
confirmatory studies in one or both sexes, implement specific pre- or post-approval study
conditions, and/or modify the design of subsequent studies.
There are limitations to interpreting clinically meaningful differences in small data sets.
Mean differences could exist between sexes due to small samples sizes; interpretation
about whether they are clinically meaningful may be premature in many cases.
VI. Recommendations for Reporting Sex-Specific
Information in Applications and Public Documents
Confidential submissions to FDA contain detailed analyses of clinical study data, which may
include a variety of sex-specific analyses. However, public documents, including labeling
and FDA summaries of review (e.g., SSED) for medical devices approved in the past, are
inconsistent with regard to the degree of information reported on device performance in
demographic subgroups. Although sponsors may be most interested in the generalizability of
the findings, individual patients and their medical providers may benefit from more data
regarding effectiveness and potential adverse events associated with device use in a
particular demographic subgroup.
A. Enrollment Demographics, Baseline Characteristics & Co-Morbidities
The strength of the conclusions of your clinical study(ies) with respect to device
performance in women and men is linked to the proportions of each sex in your
study(ies). FDA recommends that you report the number and proportion of subjects by
sex who were treated or diagnosed with your device as part of a clinical study as follows:
You should report study demographics in terms of proportion enrolled by
subgroup. You should discuss whether the proportions enrolled are consistent
with the sex-specific prevalence of disease, if known. For studies with multiple
arms, you should report enrollment proportions for each sex in each arm.
If co-morbidities and/or other baseline characteristics are collected, we
recommend that you report these by demographic subgroup as well as overall.
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For per protocol analyses, we recommend a comparison and discussion of sex-
specific differences in follow-up compared to at enrollment, for the overall study
sample and for each study arm.
You may choose to adapt the example language below, or you may use similar language
which incorporates the contents described above.
Example Language:
Women represented [34%] of the total patients enrolled in the overall study. This is
similar to the prevalence of [coronary artery disease] in the general U.S. population
[citation]. Among subjects in the treatment group, m1/n1 (p1%) were women, and m2/n2
(p2%) of subjects in the control group were women.
Women were more likely to have diabetes compared to men (35% vs. 22%) and less likely
to have prior history of myocardial infarction (24% vs. 36%).
Additionally, we recommend that you include this type of information in any applicable
tables and charts.
1. For New or Ongoing Studies (IDE study design/early enrollment stage)
You should report this information as part of your annual progress reports.
2. For Completed Studies (marketing application stage)
You should report this information as part of your marketing application in sections
containing results of clinical investigations, including the labeling. A summary of
this information should also be included in your draft PMA Summary of Safety and
Effectiveness, 510(k) Summary, or de novo decision summary.
3. For Postmarket Studies (PAS or 522 PS stage)
You should report this information in interim reports and in the results section of your
final report.
B. Sex-Specific Outcomes (Safety or Effectiveness)
Information regarding sex-specific outcomes analyses should be described in the labeling
and summaries of review, regardless of whether the analyses are pre-specified or post
hoc. Covariates that might explain possible outcome differences between sexes should
be described.
If outcome differences by sex are statistically significant and clinically
meaningful, you should report the results of the outcome analyses.
If results of these analyses suggest a sex difference in an endpoint or event that is
clinically meaningful but not statistically significant, you should report the
findings descriptively.
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If results of these analyses suggest no sex differences in outcomes, you should
report which analyses were conducted and that no differences were found.
1. For Completed Studies (marketing application stage)
When presenting results of prespecified sex analyses, we recommend the following:
Clearly state which analyses were conducted
Specify statistical methods used to assess for heterogeneity of treatment
differences by sex (as described above)
You may include inferential statistics, including p-values and/or
confidence intervals. To provide appropriate context, describe prior
scientific evidence suggesting that clinically meaningful differences by
sex are expected, or describe statistical limitations of analyses.
When presenting results of post hoc sex-specific analyses, we recommend the
following:
Clearly state that the analyses were unplanned
Clearly state which analyses were conducted
Specify statistical methods used to assess for heterogeneity of treatment
differences by sex (as described above)
Use descriptive statistics only (mean, standard deviation, etc.). Results in
confidential submissions to PMA can include inferential statistics, with a
disclaimer that these are from post hoc analyses.
If clinically meaningful sex differences in safety or effectiveness are observed, or if
there are potential differences that might require follow-up studies, data on benefits
and risks should be described separately for women and men in labeling and review
summaries.
2. For Postmarket Studies (PAS or 522 PS stage)
When presenting results of sex-specific analyses of PAS or 522 PS data, the
recommendations above should also apply.
If a clinically meaningful signal is detected in your final analysis, FDA may
recommend changes to your approved labeling and review summaries, which you
should submit with your final study report.
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APPENDIX 1 – DECISION FRAMEWORK
We encourage the use of existing scientific data (e.g., previous studies, disease science) to
determine whether there is a hypothesis for a clinically meaningful sex difference for your
device. When there is a hypothesis for a clinically meaningful sex difference, the following
decision trees provide a framework in deciding when various sex-specific statistical
recommendations apply for different clinical study designs.
RECOMMENDATIONS FOR SEX-SPECIFIC STATISTICAL DESIGN
Follow Recommendations associated with study design
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DECISION FRAMEWORK
RECOMMENDATIONS FOR SEX-SPECIFIC STATISTICAL ANALYSES FOR
COMPLETED STUDIES - ONE –ARM STUDIES
(Objective Performance Criterion, Performance goal, Observational Study)