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Newborn HAL® S3010 - Wireless and Tetherless, Neonate at 40-Weeks Gestational Age

Name: Newborn HAL® S3010 - Wireless and Tetherless, Neonate at 40-Weeks Gestational Age
Brand: HAL®
SKU: S3010.PK

In stock

Model:

S3010.PK

Newborn HAL's® true-to-life physical and physiological features, wireless mobility, and ease-of-use allow you to simulate realistic clinical cases. Whether training occurs in a simulation center, in situ, or in transit, participants of any level can practice the skills needed to provide safe and effective care to neonatal patients.

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Product Overview

Product Features

Newborn HAL® S3010
The original wireless and tetherless newborn patient simulator.

Newborn HAL® S3010 is a 40-week tetherless newborn featuring programmable spontaneous breathing, pulses, and color, and it responds to CPR like a real baby.

Wireless and tetherless

Tetherless and wireless; fully responsive during transport¹. Smoothly transitions between physiologic states in response to commands from a wireless tablet PC.

Cyanosis

Color and vital signs respond to hypoxic events and interventions.

Realistic Umbilicus

HAL’s umbilicus can be catheterized and has a pulse synchronized with programmed heart rate.

Bilateral IV arm

Newborn HAL® has bilateral IV training arms that can be used for bolus or intravenous infusions and draining fluids.

Intraosseous access

Intraosseous infusion and injection system with realistic tibia bones.

ECG monitoring

Newborn has conductive skin regions that allow the application of real electrodes to view ECGs with physiologic variations, allowing the user to track cardiac rhythms with their own equipment just like with a human patient.

Powerfully intuitive. Ready for use.

The intuitive design of UNI 3 offers the ease of use and capabilities required by even the most demanding simulation programs.

Learn just once and for all.

The design of UNI 3 is shared across our complete line of computer-controlled patient simulators. Once familiarized, you can quickly operate other Gaumard products without retraining, saving your program valuable time and money.

Includes our Neonatal Care
Simulation Learning Experiences™ scenario package.

The Neonatal Care Simulation Learning Experiences (SLEs) provide you with a library of ready-to-use, evidence-based scenarios designed to help you maximize participant’s learning through outcome-focused simulated clinical patient encounters. The package includes 8 SLEs, complete with a facilitator’s guidebook for planning, setting up, and facilitating each learning experience:

Acute Respiratory Distress Syndrome
Bronchopulmonary Dysplasia with Pulmonary Hypertension
Drug-Exposed Infant/ Neonatal Abstinence Syndrome
Early-Onset Sepsis
Late-Onset Sepsis
Nuchal Cord
Pneumonia
Shoulder Dystocia

General

Available in multiple skin tones
Tetherless and fully responsive even while being transported
Powered from an internal rechargeable battery or wall outlet
Battery capable of 300 recharges; operate the simulator for up to 4 hours²
Training Guide with both basic and advanced interactive scenarios
Use pre-programmed scenarios, modify them, or create your own quickly and easily
Installation and training worldwide
Simulation Made Easy™

Airway

Multiple upper airway sounds synchronized with breathing
Nasal or oral intubation
Right mainstem intubation
Sensors detect depth of intubation
Airway may be obstructed
Block right lung, left lung, or both lungs
Head tilt/ chin lift
Jaw thrust
Simulated suctioning techniques can be practiced
Bag-Valve-Mask Ventilation
Placement of conventional airway adjuncts
Endotracheal intubation using conventional ETTs
Sellick maneuver brings vocal cords into view

Circulation

Measure blood pressure by palpation or auscultation
Use real modified BP cuff to measure blood pressure
Korotkoff sounds audible between systolic and diastolic pressures
Pulse sites synchronized with BP and heart rate
Bilateral IV arms with fill/drain sites
Realistic flashback
SubQ and IM injection sites
Intraosseous access at tibia
Fontanelle, umbilical, and bilateral brachial pulses synchronized with ECG

Breathing

Control rate and depth of respiration and observe chest rise
Automatic chest rise is synchronized with respiratory patterns
Select independent left and right upper lung sounds
Chest rise and lung sounds are synchronized with selectable breathing patterns
Accommodates assisted ventilation, including BVM and mechanical support
Ventilations are measured and logged
Chest compressions generate palpable blood pressure waveforms and ECG artifacts
Detection and logging of ventilations and compressions
Simulated spontaneous breathing
Variable respiratory rates and inspiratory/expiratory ratios
Bilateral chest rise and fall
Unilateral chest rise simulates pneumothoraces
Normal and abnormal breath sounds

Cardiac

ECGs are generated in real-time with physiologic variations never repeating textbook patterns
Chest compressions are measured and logged
ECG monitoring using real devices; apply real electrodes to conductive skin regions
Multiple heart sounds, rates, and intensities
Heart sounds synchronized with ECG
Dynamic 12-lead ECG display with optional Vital Signs Monitor

Speech

Pre-recorded crying

Articulation and Movement

Seizure/convulsions
Muscle tone active, right arm only, left arm only, reduced and limp
Realistic rotation of the shoulder and hip joints
Legs bend at the knees
Supine or semi-recumbent positions

Other

Central cyanosis
Color and vital signs respond to hypoxic events and interventions
Fill bladder and perform Foley catheterization
Interchangeable genitalia
Umbilical catheterization
Umbilicus with two arteries and one vein – even practice cutdowns
Temperature probe placement
Insert feeding tubes
Auscultate bowel sounds
Remains fully functional even while in transit
Sensors track student actions
Changes in condition and care provided are time-stamped and logged
View the actions of up to six care providers using a responsive menu or write your own narrative
Generate and share diagnostic lab results
File sharing through Vital Signs Monitor
Links with optional recording and debriefing system integrating the event log with cameras and patient monitor
Supplied with wireless tablet PC
Create your own scenarios - add/edit
Change simulator’s condition during the scenario

Newborn HAL® S3010
Control PC preloaded with UNI® 3
RF module, battery charger / power supply
Accessories
Soft carrying case
User guide
One-Year Limited Warranty

1. Maximum wireless range will vary depending on environmental factors and conditions.
2. Battery life estimates dependent on active features and settings; results may vary.

Priced without options, discounts, or special offers. Taxes and other fees not included. Extended service plans, product installation, and training services are available. Product design and price subject to change without notice. All trademarks and/or copyright materials are the property of their respective owners. © 2020 Gaumard Scientific. Patented; other patents pending. All Rights Reserved.

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Seamless and powerful scenario integration.

Obstetric MR adds a new layer of learning to normal vaginal birth, shoulder dystocia, and breech scenarios. It integrates seamlessly with VICTORIA’s new Simulation Learning Experiences childbirth scenarios as well as your custom scenarios and on-the-fly operation.

Observe clinical intervention in real-time.

Obstetric MR, VICTORIA’s internal network of sensors, and the powerful UNI® control software work together to provide learners with real-time visual feedback. Learners can study the rotation of the pelvis and the fetal shoulder during McRoberts and suprapubic pressure maneuvers as they perform them. It is an entirely new way to observe and understand clinical cause and effect through hands-on practice.