Cerebral palsy (CP) is one of the 3 most common developmental disorders, affecting patients throughout their lives.1 The term CP refers not to a single entity, but to a group of heterogeneous, persistent developmental disorders of movement and postural control limiting patients’ activity, attributed to non-progressive, non-immutable lesions to the developing brain in the pre-, peri-, or postnatal period.1–4 The upper age limit is subject to debate, but lesions occurring up to 2 years of age are accepted.5 These motor disorders are usually accompanied by comorbidities that constitute a significant burden for patients and their relatives. These include epilepsy; sensory, cognitive, or perceptual alterations; communication and behavioural disorders; and secondary musculoskeletal disorders.6,7 CP thus represents the leading cause of motor disability in paediatric patients8 and the second most frequent cause of severe intellectual disability.1 The global prevalence of PC is estimated at 1.5-3 cases per 1000 live births.2 A study conducted in 2007 estimated global prevalence at 2.4 cases per 1000 live births.8 Recent studies have demonstrated that this rate (currently estimated at 2.1 cases per 1000 live births7) has remained stable over the last 10 years.8

A cascade of interactions between multiple risk factors and external events leads to the development of CP in the foetus or newborn. These risk factors can be classified as prenatal, perinatal, and postnatal.2 Perinatal factors have the greatest influence on risk of CP; the most significant is premature birth, followed by small size for gestational age and low birth weight.2,9,10 Multiple studies consider male sex a risk factor for CP, with a male-to-female prevalence ratio of approximately 1.4:1.9

CP can be classified by neurological subgroup and by functional ability. Neurological subtype is determined according to the limbs affected (monoparesis, hemiparesis, tetraparesis, diparesis, triparesis, or double hemiparesis), clinical signs and symptoms (spasticity, dyskinesia/dystonia, or ataxia), and muscle tone (normotonic, hypotonic, or hypertonic).6,7 The Surveillance of Cerebral Palsy in Europe programme recommends the Gross Motor Function Classification System, a reliable classification of prognostic significance that focuses more on children's functional capacity than on their limitations.2

Early diagnosis is essential to determining and implementing appropriate treatment strategies as soon as possible: in practice, early treatment onset is thought to improve treatment effectiveness.11 Clinical warning signs include delay in achieving motor milestones, seizures, weak suck, persistent closed fist, and reduced head circumference velocity. However, most patients do not present clear symptoms in the early stage; in current clinical practice, most children with CP are diagnosed at 1 or 2 years of age.10 The use of neuroimaging techniques, neurological examination, and neurophysiological assessment improves prediction. MRI reveals abnormalities in 70%-90% of children with CP.12 Treatment objectives should be established according to patient assessment and agreement between family members and professionals involved in the patient's care; patients should also participate in this process wherever possible.13,14

In recent years, with widespread access to information, advances in information and communications technology applied to the healthcare sector are bringing about changes to traditional approaches to neurological care.15 These technologies offer an opportunity to transform the sector, with more personalised, participatory, and preventive services. In this context, the phenomenon of mobile applications (apps) offers great promise in CP care. For instance, the Saliva Tracker app, developed by the Murdoch Children's Research Institute, helps the parents and carers of children with the condition to control drooling. Numerous other scientific organisations are developing and validating assessment and treatment tools for educators and healthcare professionals specialising in CP.16 There is a need for studies to classify and analyse the evidence on the available mobile apps and whether they should be recommended for patients, relatives, or medical professionals in the context of CP.

We performed a systematic review of published studies on apps either directly related to or potentially useful for CP management; the purpose of the review was to describe, analyse, and classify the applications identified.

We performed a systematic review of published studies on apps specifically designed for use with children with CP or of potential benefit in management of the disease. We also analysed other sources of information (app marketplaces).

We identified 63 apps, of which 40 were potentially useful for CP and 23 were specifically designed for the disease; of the latter group, 11 provided information, 3 were designed for assessment, and 9 focused on treatment.

Over the last 10 years, information and communications technology has been an emerging area in healthcare.35 The World Health Organization refers to the use of these technologies for health as eHealth36; the most advanced form, mHealth (mobile health),37 refers to the rapid expansion of the use of mobile devices in healthcare and the use of healthcare apps on mobile devices38; this area continues to grow exponentially.39 The term mHealth is defined as “the use of mobile wireless technologies for public health,”36 demonstrating the increasing importance of this resource for healthcare provision and public health, given the ease of use, broad reach, and great popularity of these devices. The success of health apps may lie in the fact that they increase access to information on health behaviour, services, abilities, and disease management. They also assist healthcare professionals in gathering patient data, which is beneficial for early detection of disease.36,40 Furthermore, these apps facilitate communication with healthcare professionals, giving rise to new types of relationship between patients and their relatives or healthcare professionals; this entails numerous benefits for all parties, optimising consultation times and improving treatment adherence and long-term patient monitoring.40

Smartphone sales between 2015 and early 2016 are calculated at around 1.6 billion units, with Android and Apple devices representing 97.8% of sales. The reach of mobile devices is greater than ever. The Cisco Virtual Networking Index Mobile report concludes that there will be 11.6 billion connected devices (smartphones, tablets, and laptop computers) by 2020, of which 72% will be smart devices.40 This has led to an increase in the number of apps available on the main marketplaces, with the Google Play and Apple App Store platforms offering over 2 million apps.41 Around 97000 of these are dedicated to health and medicine.18

Broekman et al.42 report an increasing trend in the development of apps targeting young children; the highest rate was recorded between 2009 and 2011, with 58% of the 100 top-selling apps falling into this category. At this stage of life, parents play a key role in the selection and use of apps for children; however, very little is currently known about how parents’ needs are prioritised. A healthcare project run at children's hospitals by the Murdoch Children's Research Institute included mHealth tools intended to facilitate diagnosis and monitoring of disease, to increase patient participation, and to improve adherence to pharmacological treatment/rehabilitation for disorders including autism spectrum disorders and CP.43

Our study analyses applications related to CP identified in a search of biomedical databases and app marketplaces. However, given the immense number and variety of apps available, it is likely that other potentially useful apps (such as those for developing fine motor skills or hand-eye coordination, or providing information for parents or carers) may not have been included due to the difficulty of categorising them and the constant expansion of the market. Similarly, the heterogeneity of the disorders included under the term cerebral palsy and the associated comorbidities mean that other potentially useful apps (such as those for controlling epilepsy and communication or behavioural disorders) may not have been analysed. According to the Doctoralia report on health and the Internet,44 published in 2015, the most widely used applications are those providing health information (86% of survey respondents), followed by apps focusing on physical exercise (77%), diet (66%), and medication management (66%). This appears to coincide with the results of our search of the main app marketplaces: information apps were the most numerous both in the group of specifically designed apps and in the group of potentially useful apps for CP. However, the literature search identified no studies on this type of app; it is therefore necessary to question the accuracy of the information provided by some mHealth apps.

The findings from our literature search indicate that mobile devices are useful for performing certain patient evaluations, such as estimating the risk of hip dysplasia in children with CP19 and detecting dystonia, given the precision of touchscreens23; however, the poor methodological quality of the studies analysed represents a limitation for recommending routine use of these apps. Other apps aim to support diagnosis of CP, among other neurodevelopmental disorders.21 However, caution should be exercised when interpreting this information, given the very poor methodological quality of the majority of the studies analysed.

The US Food and Drug Administration (FDA) acknowledges that progress in digital health offers an opportunity for better, more efficient patient care and improved health outcomes. This gives rise to the need for many medical devices to be interoperable with other types of device and with various types of health information technology,45 which may explain the use of additional sensors, as was the case for 2 of the apps analysed in this review.20,23 While one of the main issues facing the use of apps is the lack of effective security legislation, patients appear to be comfortable using apps or web tools to submit health information.16,45

Although some apps were developed by foundations or associations specialising in CP, such as UPACE San Fernando and the Cerebral Palsy Lanka Foundation (Cerebral Palsy app), many have not been approved by such bodies. Guidelines published for developers and users provide information on the FDA regulations for the sector.45 The main issue with these regulations is the constant innovation in mHealth apps, which makes it very difficult for developers to obtain FDA approval quickly enough to keep up to date.46

Our findings show that while a range of apps are available for management of CP, very few are scientifically validated, making this an interesting field of research. Other literature reviews describe mobile applications in other areas or for other diseases, and the effectiveness of these apps. A 2014 review by Juárez-Giménez39 assessed the potential effectiveness of apps as tools for pharmacotherapy consultation and for improving adherence to prescribed treatments. The author concludes that while they may improve treatment adherence, given the great accessibility and low cost of apps, the evidence on their use is limited. To date, these apps are considered a potentially useful strategy for improving adherence. In 2017, a review by Linares-del Rey et al.47 studied apps designed for patients with Parkinson's disease, identifying a broad range of apps, many of which were developed by foundations and other organisations. However, the limited evidence and the lack of an appropriate means of evaluating the apps prevents generalisations being made regarding their use. In a recent report, Leijdekkers and Gay46 argue that mHealth would be part of a possible solution for implementing changes in healthcare provision, particularly for the prevention and treatment of chronic disease; our results may further support this.

Our study has a number of limitations. Firstly, we may have consulted too few databases, and we limited the articles selected to those written in English and Spanish. Furthermore, the app market is constantly changing and evolving; we may therefore have failed to identify some relevant apps, and new apps may have become available after the publication of this review.

We identified 63 apps cited in published articles in biomedical databases and on app marketplaces; of these, 40 were potentially useful for CP and 23 were specifically designed for the disease. Of the latter group, 11 offered information on the disease, 3 focused on assessment, and 9 were designed to treat aspects of the disease.

Numerous mobile apps are potentially useful or specifically designed for CP. However, despite the available scientific evidence, the poor methodological quality of the studies identified prevents us from recommending generalised use of these apps.

The potential benefits and risks associated with mHealth give rise to a need for further research and for official regulation of the sector. This would guarantee the reliability and safety of using this technology, providing healthcare professionals, patients with CP, and their relatives and carers with an effective adjuvant tool for diagnosis or treatment of the disease.

None.