You can download Smart Grammar and Vocabulary workbooks and textbooks for free without any registration, by direct link, in pdf format. Audio courses and lessons are available in mp3 format and you will soon be able to listen to them online. Files are not downloaded by torrent or Google Drive but directly from our server. All files are zip archives and constantly tested for viruses.
Smart junior 1 cd download
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French, German, Japanese and Spanish translations of the SASB Standards are available. To download translations of the Standards, please select your industry(ies) and fill out the form.
The first mobile device that incorporated both communication and computing features was the Blackberry, which was introduced in 2002.5 After the Blackberry was brought to market, other handheld mobile devices were introduced. Perhaps most notably, in January 2007, Apple launched the first-generation iPhone.5 Subsequently, smartphones that run the Google Android operating system were introduced in October 2008.5 Because of the intuitive touch-screen user interfaces and advanced features and capabilities that the iPhone and Android smartphones offer, ownership of mobile devices has increased rapidly.12 In April 2010, Apple introduced a new innovation, the iPad tablet computer, which because of ease of use, portability, and a comparatively large screen was yet another transformative computing tool.5 The iPad ignited the tablet computer market.9 Tablets that run the Google Android operating system (Samsung Galaxy and others) were launched later that year, making the use of these mobile devices even more widespread.5
Prior to the development of mobile devices, these resources were mainly provided by stationary computers, which do not support the need for mobility in health care settings.7 In an attempt to address this need, some health care environments set up portable, wireless mobile information stations such as Computers on Wheels (COWs) or Workstations on Wheels (WOWs).7 With the availability of mobile devices, however, clinicians now have access to a wellspring of information at their fingertips, through their smartphones and tablets.10
The ability to download medical apps on mobile devices has made a wealth of mobile clinical resources available to HCPs.15 Medical apps for many purposes are available, including ones for electronic prescribing, diagnosis and treatment, practice management, coding and billing, and CME or e-learning.9,10 A broad choice of apps that assist with answering clinical practice and other questions at the point of care exist, such as: drug reference guides, medical calculators, clinical guidelines and other decision support aids, textbooks, and literature search portals.7,13,15 There are even mobile apps that simulate surgical procedures or that can conduct simple medical exams, such as hearing or vision tests.6,7 Many mobile apps are not intended to replace desktop applications, but are meant to complement them in order to provide a resource that has the potential to improve outcomes at the point of care.7 The use of medical apps has become frequent and widespread; 70% of medical school HCPs and students reported using at least one medical app regularly, with 50% using their favorite app daily.1,9
An additional advantage provided by information management apps is that they can be used in combination. For example, GoodReader can be connected to a cloud service, allowing PDF files to be downloaded from the cloud into the reader app.5 Evernote, as well as some other information management apps, can be used in conjunction with a cloud service and reader.5 This enables a PDF downloaded from the cloud to be viewed with a reader, then sections of the document can be cut and pasted into the information management app.5
Specialized apps are also available for remote viewing of medical imaging scans.10 Mobile MIM is a free app for the iPad and iPhone, approved by the Food and Drug Administration, that allows remote viewing of x-rays and imaging scans when users cannot access imaging workstations.6 This software works with a paid subscription or pay-per-use plan using MIMCloud, a HIPAA-compliant server that allows users to store and share medical images.6 Images can be downloaded from the cloud and viewed with the MIMViewer paid app in any setting, whether during discussions with team members or patients.6
American Heart Association (AHA) USB drives are compatible with Windows and Macintosh computers with standard USB-A ports. A USB hub or adapter may be used with computers that have USB-C ports. There is no need to download or purchase other software to operate the USB drives.AHA USB drives are intended for use on either Windows or Mac. The player on the Heartsaver USB -- Flux Player -- is not supported on Chrome OS; Heartsaver USB drives currently do not work on Chromebooks.View the Heartsaver USB troubleshooting guide here (PDF).View the BLS, ACLS, and PALS USB troubleshooting guide here (PDF).
The APH product manuals below are free-of-charge downloads. You may print or emboss them as needed. We do not keep these manuals in stock, but make them on demand as orders are placed for them; therefore, please allow several weeks for delivery.
Note: Manuals on this download page may be available from APH in other formats that are not shown; for example, the braille manual for a kit may be available for free download, but the large print manual may ONLY be available for purchase, and will therefore not appear on this download page.
Download the LeapFrog Connect Application for LeapReader at leapfrog.com/connect; it will walk you through the setup process for your LeapReader, including downloading additional Companion Audio for your device. You can also touch an inside page of your books with your LeapReader and then connect the device to the computer via USB cord; the books' Companion Audio will then download automatically to your LeapReader after the LeapFrog Connect application opens on your desktop.
Arkansas will implement COVID-19 SMART Health Cards beginning September 14. When you receive a COVID-19 vaccination record from the Arkansas Department of Health or your health care provider and the record is from the state immunization information system, WebIZ, the record will contain your COVID-19 vaccination history and a 2D barcode, commonly known as a QR code. The QR code may be scanned into an app on your smartphone and used to verify your COVID-19 vaccination history at places that have a SMART Health Card compatible verifier app, such as airports, business, and large venues. If a SMART Health Card compatible verifier app is not available, you may present the paper copy of your SMART Health Card.
Apart from these 2 examples, wearables are applied in diverse fields of health, including acoustic, gastrointestinal sensors for ileus prediction [18]; UV sun exposure [19]; heat-related illness measurements [20]; electrolyte monitoring, for example, for cystic fibrosis or training management [21,22]; early warning of AF with a wearable ring [23]; generation of electrocardiograms (ECGs) [15]; measurement of cardiopulmonary resuscitation quality [24]; measurement of continuous noninvasive blood glucose [25], as well as smart inhalers and activity trackers for asthma monitoring [26].
Numerous reviews and studies have investigated validation and accuracy, particularly for specific affordable wearables, comparing these to the gold standard measurements [21] or comparing evidence in a meta-analysis [8]. Many studies have focused on novel technologies, presenting prototypes, or investigating the feasibility and acceptance of a wearable device in a specific setting [3,27]. Similarly, reviews on the application and potential of wearables have focused on (1) specific wearable devices or specific wearable measurements, for example, only smartwatches [4] or only sleep measurements [28] or (2) applications of specific medical fields and interventions, for example, only for diagnosis and treatment in cardiological conditions [29] or wearables as an intervention to promote PA in patients with oncologic conditions [30]. Among these publications, we identified a lack of aggregated insight for wearable use in health research and its respective strengths and shortcomings.
Studies not analyzing wearable-generated data for (health) outcome assessment, including studies focusing on (1) accuracy, validation, improvement (algorithms and software); (2) patents; (3) smart clothing; (4) obtrusive wearables (the device comprises obstructive parts or wires, etc); (5) behavior change intervention studies (ie, where the wearable is provided as promotion for more physical activity only and not for health outcome assessment); (6) qualitative studies; or (7) studies with research objectives and outcomes not related to health or a medical condition
Fitness trackers (86/189, 45.5%) and accelerometers (measuring body movement acceleration [37]) worn on the wrist, torso, and hip (49/189, 25.9%) were the most frequent. Other wearable device types included ECG chest straps and patches (21/189, 11.1%), smartwatches (12/189, 6.3%), and distinct vital sign trackers (10/189, 5.3%) such as oximetry rings or blood pressure armbands (Table 2).
Multiple studies (51/179, 28.5%) described wearables as objective and superior to self-reported outcomes as they were more accurate, reliable, and easier to generate. Often, the authors valued the relatively low costs of wearables (50/179, 27.9%). Others appreciated wearables as being unobtrusive or noninvasive (48/179, 26.8%) and enabling continuous, long-term measurements (38/179, 21.2%). Furthermore, the handling (37/179, 20.7%) of hardware and software was often found to be user-friendly, as well as the prevalence of wearables in the population (27/179, 15.1%), decreasing stigma and easing participant recruitment. Some studies (26/179, 14.5%) reported that participants accepted and liked the wearables, resulting in high participant compliance (wearing and using the wearable). Some authors (18/179, 10.1%) perceived technical wearable characteristics as positive, for example, good sampling rate of measurements, long battery life, large memory space, raw data availability, data security, compatibility with other devices such as smartphones, and availability of application programing interfaces (APIs). 2ff7e9595c
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