BIOTRONIK Eluna 8, Eluna 8 SR, Eluna 8 DR-T, Eluna 8 HF-T, Eluna 8 SR-T Technical Manual

BIOTRONIK SE & Co. KG
Woermannkehre 1
12359 Berlin · Germany
Tel +49 (0) 30 68905-0
Fax +49 (0) 30 6852804
sales@biotronik.com
www.biotronik.com

Eluna 8

SR(-T), DR(-T), HF-T (Pr oMRI

®

)

Pacemaker | Bradyarrhythmia Therapy | 
Cardiac Resynchronization Therapy

Technical Manual

403587

Revision: F (2014-08-04)

© BIOTRONIK SE & Co. KG

All rights reserved.
Specification subject to modification, revision and improvement.

® Registered trademarks of BIOTRONIK SE & Co. KG:

BIOTRONIK Home Monitoring, Eluna, ProMRI

Index 403587Technical ManualEluna SR(-T), DR(-T), HF(-T)

0123
0681 2014

2 Table of Contents

Table of Contents

Table of Contents

Product Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3

Intended Medical Use . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3

Indications. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3

Contraindications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4

System Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5

Diagnostic and Therapy Functions . . . . . . . . . . . . . . . . . . . . . 8

General Safety Instructions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10

Operating Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10

Possible Complications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11

Possible Risks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12

Implantation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14

Implantation Procedure. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14

Precautionary Measures while Programming. . . . . . . . . . . 17

Magnet Response. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19

Follow-up . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20

Patient Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20

Replacement Indications . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21

Explantation and Device Replacement . . . . . . . . . . . . . . . . . 22

Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23

Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23

Pacing and Sensing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25

Rate Adaptation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27

MRI Program . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28

Preset Programs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28

Tolerances of Parameter Values . . . . . . . . . . . . . . . . . . . . . 30

Technical Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31

Mechanical Characteristics. . . . . . . . . . . . . . . . . . . . . . . . . . 31

Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . 31

Battery Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32

Legend for the Label . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35

3 Product Description

1 Product Description

Product Description1403587Technical ManualEluna SR(-T), DR(-T), HF(-T)

Intended Medical Use

Intended use Eluna is a family of implantable pacemakers that may be implanted for all brady-

cardia arrhythmia indications. The primary objective of the therapy consists of
improving patients' symptoms that can be clinically manifested. The implantation of
the pacemaker is a symptomatic therapy with the following objective:

• Compensation of bradycardia by atrial, ventricular, or AV sequential pacing

• Additional triple-chamber features: Resynchronization of ventricular chamber
contraction via biventricular pacing

Diagnosis and

therapy forms

The cardiac rhythm is automatically monitored and bradycardia arrhythmias are
treated. All major therapeutic approaches from the field of cardiology and electro-

physiology are unified in this pacemaker family. BIOTRONIK Home Monitoring

®

enables physicians to perform therapy management at any time.

Required expertise In addition to having basic medical knowledge, the user must be thoroughly familiar

with the operation of a device system.

• Only qualified medical specialists having the special knowledge required for the
proper use of implanted devices are permitted to use them.

• If users do not possess this knowledge, they must be trained accordingly.

Indications

Guidelines of

cardiological societies

Generally approved differential diagnostic methods, indications, and recommenda­tions for pacemaker therapy apply to BIOTRONIK devices.

The guidelines provided by cardiology associations offer decisive information:

• We recommend observing the indications published by the German Cardiac
Society (Deutsche Gesellschaft für Kardiologie, Herz- und Kreislaufforschung)
and the ESC (European Society of Cardiology).

• This also applies to the guidelines published by the Heart Rhythm Society (HRS),
the American College of Cardiology (ACC), the American Heart Association
(AHA), and other national cardiology associations.

Device types For the following symptoms/expectations, the following device types are indicated:

Symptom/expectation SR DR HF

Disorientation due to bradycardia x x x
Presyncope x x x
Benefit from resynchronization of the right and left

ventricles

x

Syncope x x x

4 Product Description

Pacing modes For the following symptomatic, the following pacing modes are indicated:

MR conditional

ProMRI® labeled MRI conditional pacemakers are safe for use in the MRI environ­ment when used in conjunction with a complete MRI conditional pacing system and
according to the instructions given in the ProMRI® manual.

Contraindications

Guidelines No contraindications are known for the implantation of multifunctional single-

chamber, dual-chamber or triple-chamber devices, provided differential diagnos­tics precedes implantation according to the appropriate guidelines and no modes or
parameter combinations are configured that pose a risk to the patient.

Pacing modes

and parameters

The compatibility and effectiveness of parameter combinations must be checked
and, as the case may be, adapted after programming.

Symptom/expectation Pacing mode

Sick sinus syndrome Dual-chamber pacing
Chronic, symptomatic second and third-degree AV block Dual-chamber pacing
Adams-Stokes syndrome Dual-chamber pacing
Symptomatic bilateral bundle branch block when tach-

yarrhythmia and other causes have been ruled out

Dual-chamber pacing

• Chronotropic incompetence

• Benefit from increased pacing rate with physical
activity

R mode or CLS

Sinus node dysfunction in the presence of normal AV and
intraventricular conduction

Atrial pacing

Bradycardia in conjunction with the following:

• Normal sinus rhythms with only rare episodes of 
AV block or sinus arrest

• Chronic atrial fibrillation

• Severe physical disability

Ventricular pacing

Set of facts Contraindicated pacing mode

Additionally implanted ICD Unipolar pacing

Set of facts Inappropriate pacing mode

Chronic atrial tachycardia, chronic
atrial fibrillation or flutter

Atrial-controlled modes (DDD, VDD,
AAI)

Poor tolerance of pacing rates above the
basic rate, e.g., angina pectoris

AV conduction disorder Atrial single-chamber pacing
Failing AV conduction

Set of facts Adapt parameters

Slow retrograde conduction after
ventricular pacing: Risk of pacemaker­mediated tachycardia

• Extend atrial refractory period (ARP)
and/or:

• Shorten AV delay

•Rarely:
Program to DDI, DVI or VVI

Poor tolerance of pacing rates above the
basic rate, e.g., angina pectoris

• Lower atrial upper rate

• Lower maximum sensor rate

• Deploy atrial overdrive pacing

5 Product Description

System Overview

Note: Use only adapters approved by BIOTRONIK for leads with different connec-

tions.

• If you have any questions concerning the compatibility of other manufacturers'
leads, please contact BIOTRONIK.

Device family This device family consists of single-chamber, dual-chamber and triple-chamber

devices with or without Home Monitoring. Not all device types are available in every
country.

The following device variants are available:

Device The device's housing is made of biocompatible titanium, welded from the outside

and therefore hermetically sealed. The ellipsoid shape facilitates ingrowth into the
pectoral muscle area. The housing serves as an antipole in the case of unipolar lead
configuration.

IS-1 lead connection The device labeling provides information pertaining to the connection assignment:

Leads BIOTRONIK leads are sheathed in biocompatible silicone. They can be flexibly

maneuvered, are stable long-term, and are equipped for active or passive fixation.
They are implanted using a lead introducer set. Some leads are coated with poly­urethane to increase the gliding properties of the lead. Leads with steroids reduce
inflammatory processes. The fractal design of the leads allows for low pacing
thresholds, high pacing impedance, and a low risk of oversensing.

BIOTRONIK provides adapters to connect already implanted leads to new devices.

Telemetry Telemetric communication between the device and the programmer can be carried

out following initialization either by applying the programming head (PGH) to the
device or by using radio frequency (RF) telemetry in the programmer. BIOTRONIK

calls this function SafeSync

®

.

Device type Variant with

Home Monitoring

Variant without
Home Monitoring

Single-chamber Eluna 8 SR-T Eluna 8 SR
Dual-chamber Eluna 8 DR-T Eluna 8 DR
Triple-chamber Eluna 8 HF-T —

SR DR HF

Connector
port

Lead
connector

Configuration Implantation site Device type

RA IS-1 Unipolar, bipolar Atrium DR, HF
RV IS-1 Unipolar, bipolar Right ventricle SR, DR, HF
LV IS-1 Unipolar, bipolar Left ventricle HF

VVIR /AAIR

IS-1

DDDR

A

IS-1

DDDR

A

IS-1

V

LV

RV

Note: Home Monitoring is possible in all modes.

6 Product Description

Programmer Implantation and follow-up are performed with BIOTRONIK's portable

programmer: There are programmers with integrated or external SafeSync Module
for RF telemetry.

The programmer is used during implantation to transfer the current device
program to the device. The pacing thresholds can be determined and all tests can
be performed during in-office follow-up. In addition to this, the programmer is used
to set mode and parameter combinations, as well as for interrogation and saving of
data from the device. Leadless ECG, IEGM, markers and functions are displayed
simultaneously on the color display.

Modes The mode setting depends on the individual diagnosis:

NBG codes AAIR or VVIR is the NBG code for the antibradycardia mode of the single-chamber

device:

DDDR is the NBG code for the antibradycardia mode of the dual-chamber device:

Device type Modes Standard

SR(-T) • VVI-CLS (8 series only)

• VVIR; V00R; AAIR; A00R

• VVI; VVT; V00; AAI; AAT; A00

•OFF

VVIR

DR(-T) • VVI-CLS; DDD-CLS (8 series only)

• DDDR; DDIR; DVIR; D00R
VDDR; VDIR; VVIR; V00R

AAIR; A00R

• DDD; DDT; DDI; DVI; D00
VDD; VDI; VVI; VVT; V00

AAI; AAT; A00

• DDD-ADI; DDDR-ADIR

•OFF

DDDR

HF-T • DDD-CLS; VVI-CLS

• DDDR; DDIR; DVIR; D00R
VDDR; VDIR; VVIR; V00R

AAIR; A00R

• DDD; DDT; DDI; DVI; D00
VDD; VDI; VVI; VVT; V00

AAI; AAT; A00

• DDD-ADI; DDDR-ADIR

•OFF

DDDR

A/V Pacing in the atrium or ventricle
A/V Sensing in the atrium or ventricle
I Pulse inhibition in the atrium and ventricle
R Rate adaptation

D Pacing in the atrium and ventricle
D Sensing in the atrium and ventricle
D Pulse inhibition and pulse triggering
R Rate adaptation

7 Product Description

DDDRV is the NBG code for the antibradycardia mode of the triple-chamber device:

BIOTRONIK

Home Monitoring

®

In addition to effective pacing therapy, BIOTRONIK provides a complete therapy
management system:

• With Home Monitoring, diagnostic and therapeutic information and technical
data are automatically sent to a stationary or mobile transmitter via an antenna
in the device header. The data are encrypted and sent from the transmitter to
the BIOTRONIK Service Center via the cellular phone network.

• The received data are deciphered and evaluated. Each physician can set the
criteria for evaluation to be used for each patient and can configure the time of
notification via e-mail, SMS or fax.

• A clear overview of the results of this analysis is displayed for the attending
physicians on the protected internet pl

atform Home Monitoring Service Center

(HMSC).

• Data transmission from the device is performed with a daily device message.

• Device messages which indicate special events in the patient's heart or in the
device are forwarded immediately.

• A test message can be initiated at any time using the programmer to immedi­ately check the Home Monitoring function.

Order numbers Eluna The devices can be obtained as follows:

Package contents The storage package includes the following:

• Sterile packaging with device

• Serial number label

• Patient ID card

• Warranty booklet

Note: The technical manual pertaining to the device is either included in hard copy
form in the storage package or in digital form on the internet.

The sterile container includes the following:

•Device

• Screwdriver

D Pacing in the atrium and ventricle
D Sensing in the atrium and ventricle
D Pulse inhibition and pulse triggering
R Rate adaptation
V Multisite pacing in both ventricles

Device type Eluna 8 Eluna 8 ProMRI

SR 394939 394972
SR-T 394934 394971
DR 394927 394970
DR-T 394929 394969
HF-T 394917 394968

8 Product Description

Diagnostic and Therapy Functions

General overview All the systems have extensive features that allow quick diagnosis and delivery of

safe therapy for bradycardia conditions.

• Automatic functions make it easy and fast to implant, configure, and check the
pacemaker.

• Auto-initialization after implantation: The device recognizes the implanted leads
autonomously and sets the polarity. The automatic functions of the software are
activated after 10

min.

Diagnostic functions • Data from the last 10 interrogations and follow-ups are recorded as well as

arrhythmia episodes; they are stored together with other data to assess patients
and the state of the device at any time.

• Continuous automatic below-threshold impedance measurements are
performed in the device independent of the pacing pulse in order to check the
lead for proper functioning.

• Once a telemetry connection has been established during a test procedure in an
in-office follow-up, the IEGM is displayed with markers.

Antibradycardia pacing • Sensing: The amplitudes of the P and R waves are measured in the implanted

device fully automatically to record varying amplitudes. The sensitivity for the
atrium and ventricle is adapted automatically on an ongoing basis. The
measurement data are averaged and the trend can be displayed.

• Thresholds: atrial as well as ventricular pacing thresholds are automatically
determined in the device. Capture control is used to set the pulse amplitudes so
that pacing is performed with the optimum atrial and ventricular amplitude for
the patients with each change of the pacing threshold.

• Timing: Pacing in the atrium is checked particularly carefully by an automatic
adaptation of the atrial refractory period in order to avoid pacemaker-mediated
tachycardia.(Auto PVARP function: the postventricular atrial refractory period is
adapted automatically).

• Additional, special form of rate adaptation with devices from the 8 series: an
increased cardiac output requirement is detected using physiological imped

­ance measurement. The measuring principle is based on contractile changes
(ionotropy) of the myocardium (CLS function: Closed Loop Stimulation). Rate
adaptation is automatically initialized and optimized in CLS mode.

• Ventricular pacing suppression with devices from the 8 series: unnecessary
ventricular pacing is avoided by promoting intrinsic conduction (Vp suppression
function). The device can adapt itself to conduction changes. In the case of
intrinsic conduction, the device switches to a DDD(R)-ADI(R) mode.

Resynchronisation therapy Triple chamber devices have functions to configure different VV delays in order to

resynchronize the ventricles.

• Capture Control is available for the left ventricle with automated tracking of the
pacing threshold or automatic threshold monitoring (ATM) for trend analysis.

• To ensure that no additional surgery is necessary in case of a left-sided increase
of pacing threshold or undesired phrenic nerve stimulation, different pacing
polarities can be set for the left ventricular lead with a triple-chamber device.

• An additional diagnostic function with biventricular pacing: variability of the
heart rate, the patient activity and the thoracic impedance are monitored on a
continual basis.

9 Product Description

Programs There are two types of therapy programs:

• Default parameters are offered for the most common indications (Program
Consult function).

• Individual settings can be saved in 3 individual therapy programs.

Home Monitoring functions The device automatically sends information to the transmitter once a day. Addition-

ally, the test messages can be initiated using the programmer. Important medical
information includes, among others, the following:

• Ongoing atrial and ventricular arrhythmia

• Parameters relevant to leads in the atrium and ventricle: thresholds, sensing
amplitudes, impedances

• Current statistics on bradycardia therapy

• Individually adjustable timing interval for device messages which provide addi­tional information pertaining to the device messages

• IEGM online HD® with up to 3 high definition channels

• Transmission of these IEGM recordings along with device messages

10 General Safety Instructions

2 General Safety Instructions

General Safety Instructions2403587Technical ManualEluna SR(-T), DR(-T), HF(-T)

Operating Conditions

Technical manuals The following technical manuals provide information about usage of the device

systems:

— Technical manual for the device

— Technical manual for the HMSC

— Technical manuals for the programmer and its accessories

— Technical manuals for the user interface

— Technical manuals for cables, adapters and accessories

• Technical manuals are either included in hard copy form in the storage package
or in digital form on the internet:

manuals.biotronik.com

• Follow all relevant technical manuals.

• Preserve technical manuals for later use.

Care during shipping and

storage

• Devices are not to be stored close to magnets or sources of electromagnetic
interference.

• Note the effects of the storage duration; see Battery Data.

Temperature Extremely low and high temperatures affect the service time of the battery in the

device.

• The following temperatures are permitted for transport, storage, and use:
–10°C to 45°C

Sterile delivery The device and the screwdriver have been gas-sterilized. Sterility is guaranteed only

if the blister and quality control seal have not been damaged.

Sterile packaging The device and screwdriver are each packaged in 2 separately sealed blisters. The

inner blister is also sterile on the outside so that it can be transferred in a sterile
state during implantation.

Single use only The device and screwdriver are intended for single use only.

• Do not use the device if the package is damaged.

• The device must not be resterilized and reused.

11 General Safety Instructions

Possible Complications

General information on

medical complications

Complications for patients and device systems generally recognized among practi­tioners also apply to BIOTRONIK devices.

• Normal complications may include fluid accumulation within the device pocket,
infections, or tissue reactions. Primary sources of complication information
include current scientific and technological knowledge.

• It is not possible to guarantee the efficacy of antitachycardia therapy, even if the
programs have proven successful during tests or subsequent electrophysiolog

­ical examinations. In rare cases the set parameters may become ineffective. In
particular it is inevitable that tachyarrhythmias may be induced.

Skeletal myopotentials Bipolar sensing and control of sensitivity are adapted by the device to the rate range

of intrinsic events so that skeletal myopotentials are usually not sensed. Skeletal
myopotentials can nonetheless be classified as intrinsic events especially with a
unipolar configuration and/or very high sensitivity and, depending on the interfer­ence, may cause inhibition or antiarrhythmia therapy.

Nerve and muscle

stimulation

A device system consisting of a unipolar lead and an uncoated device may result in
undesirable pacing of the diaphragm in the case of an initial or permanent high
setting of the pulse amplitude.

Possible technical failures Technical failure of a device system cannot be entirely ruled out. Possible causes

may include the following:

• Lead dislodgement

• Lead fracture

• Insulation defects

• Device component failures

• Battery depletion

Electromagnetic

interference (EMI)

Any device can be sensitive to interference, for example, when external signals are
sensed as intrinsic rhythm or if measurements prevent rate adaptation.

• BIOTRONIK devices have been designed so that their susceptibility to EMI is
minimal.

• Due to the intensity and variety of EMI, there is no guarantee for safety. It is
generally assumed that EMI produces only minor symptoms in patients - if any.

• Depending on the pacing mode and the type of interference, sources of interfer­ence may lead to pulse inhibition or triggering, an increase in the sensor-depen­dent pacing rate or asynchronous pacing.

• Under unfavorable conditions, for example during diagnostic or therapeutic
procedures, interference sources may induce such a high level of energy into
the pacing system that the cardiac tissue surrounding the lead tip is damaged.

Device behavior

in case of EMI

In the case of electromagnetic interference or undesired myopotentials, the device
switches to asynchronous pacing for the duration of the time that the interference
rate is exceeded.

Static magnetic fields The reed switch in the pacemaker starts to close at a field strength of 1.5 mT.

12 General Safety Instructions

Possible Risks

Procedures to avoid The following procedures must be avoided as they may cause harm to the patient or

damage the device and, as a result, put the system functionality at risk:

• Therapeutic ultrasound

• Transcutaneous electrical nerve stimulation

• Hyperbaric oxygen therapy

• Applied pressures higher than normal pressure

Potentially risky therapeutic

and diagnostic procedures

If electrical current from an external source is conducted through the body for diag­nostic or therapeutic purposes, then the device can be subjected to interference and
the patient placed at risk.

Arrhythmia or ventricular fibrillation can be induced during diathermic procedures
such as electrocautery, HF ablation or HF surgery. For example, damaging pres­sure levels may arise during lithotripsy. Influences on the device are not always
immediately clear.

If potentially risky procedures cannot be avoided, the following should be observed
at all times:

• Electrically insulate patients.

• Switch the pacemaker function to asynchronous modes if needed.

• Do not introduce energy near the device system.

• Check the peripheral pulse of the patient.

• Monitor the patient during and after every intervention.

External defibrillation The device is protected against the energy that is normally induced by external defi-

brillation. Nevertheless, any implanted device may be damaged by external defibril­lation. Specifically, the current induced in the implanted leads may result in necrotic
tissue formation close to the electrode/tissue interface. As a result, sensing prop­erties and pacing thresholds may change.

• Place adhesive electrodes anterior-posterior or perpendicular to the axis
formed by the device to the heart at least 10 cm away from the device and from
implanted leads.

Radiation therapy The use of radiation therapy must be avoided due to possible damage to the device

and the resulting impaired functional safety. If this type of therapy is to be used
anyway, prior risk/benefit analysis is absolutely necessary. The complexity of influ­encing factors such as different sources of radiation, a variety of devices and
therapy conditions makes it impossible to issue directives that guarantee radiation
therapy without an impact on the device. The EN 45502 standard pertaining to active
implantable medical devices requires the following measures during the adminis­tration of therapeutic ionizing radiation:

• Adhere to instructions for potentially risky therapeutic and diagnostic proce­dures.

• Shield device against radiation.

• After applying radiation, double-check the device system to make sure it is func­tioning properly.

Note: Please contact BIOTRONIK with questions on the risk/benefit analysis.

13 General Safety Instructions

Magnetic resonance

imaging

Magnetic resonance imaging must be avoided due to the associated high frequency
fields and magnetic flux density: Damage or destruction of the device system by
strong magnetic interaction and damage to the patient by excessive warming of the
body tissue in the area surrounding the device system.

Under certain conditions and when maintaining mandatory measures, magnetic
resonance imaging can be performed to protect patient and device system.
BIOTRONIK devices with the "MR conditional function bear the identification
ProMRI

®

.

•The ProMRI® manual – MR conditional device systems – contains detailed infor­mation on safely conducting an MRI.

— Download the digital manual from the web site:

manuals.biotronik.com

— Order the printed manual at BIOTRONIK.

• Does approval as "MR-Conditional" apply in your country or region? Ask for
current information at BIOTRONIK.

14 Implantation

3 Implantation

Implantation3403587Technical ManualEluna SR(-T), DR(-T), HF(-T)

Implantation Procedure

Having parts ready The following parts that correspond to the requirements of the EC Directive 90/385/

EEC are required:

• Device with screwdriver from BIOTRONIK

• BIOTRONIK leads and lead introducer set
— Single-chamber device: unipolar or bipolar lead for the right ventricle

— Double-chamber device: one unipolar or bipolar lead each for the atrium

and for the right ventricle

— Triple-chamber device: an additional unipolar or bipolar LV lead

• Approved connections are IS-1: Use only adapters approved by BIOTRONIK for
leads with different connections or leads from other manufacturers.

• BIOTRONIK programmer (with integrated SafeSync RF telemetry or with sepa­rate SafeSync Module) and approved cables

• External multi-channel ECG device

• Keep spare parts for all sterile components.

Keeping an external

defibrillator ready

In order to be able to respond to unforeseeable emergencies or possible technical
failures of the device:

• Keep an external defibrillator and paddles or patch electrodes ready.

!

!

WARNING
Inadequate therapy due to defective device

If an unpacked device is dropped on a hard surface during handling, electronic
parts could be damaged.

• Use a replacement device.

• Return the damaged device to BIOTRONIK.

Unpacking the device

• Peel the sealing paper off of the outer blister at the marked position in the direc­tion indicated by the arrow. The inner blister must not come into contact with
persons who have not sterilized their hands or gloves, nor with non-sterile
instruments!

• Use the gripping tab on the inner plastic container to remove it from the outer
plastic container.

• Peel the sealing paper off of the sterile inner blister at the marked position in
the direction indicated by the arrow.

Note: The device is disabled on delivery and can be implanted immediately after
unpack

ing without manual activation.

Checking parts Damage to any of the parts can result in complications or technical failures.

• Check for damage before and after unpacking all parts.

• Replace damaged parts.

Note: If necessary, the device can also be programmed before or during auto­initialization.

15 Implantation

Implantation site In general, the pacemaker is implanted on the right side subcutaneously or subpec-

torally, depending on the lead configuration as well as the anatomy of the patient.

Overview: Implanting

Avoid damage to the header Set screws must be tightened or loosened with care.

• Loosen set screws with the supplied screwdriver. Use only BIOTRONIK screw­drivers with torque control!

• If lead revision is necessary, re-order sterile screwdrivers from BIOTRONIK.

!

!

WARNING
Short circuit due to open lead connector ports

Connector ports in the header which are open and thus not electrolyte-proof may
cause undesired current flows to the body and penetration of body fluid into the
device.

• Close unused connections with IS-1 blind plugs.

!

!

WARNING
Inadequate therapy

Insufficient lead spacing or inappropriate lead positioning may lead to far field
sensing.

• Tip and ring electrodes must not have contact with each other.

Preventing short circuits

in the header

Keeping distance

between leads

1 Shape the device pocket and prepare the vein.
2 Implant the leads and perform measurements.
3 Connect device and leads.

The device starts auto-initialization on its own.
4 Insert the device.
5 Guide the fixation suture through the opening in the header and fixate the

device in the prepared device pocket.
6 Close the device pocket.
7 Prior to testing and configuration, wait for the successful completion of auto-

matic device initialization.

16 Implantation

Connecting the lead

connector to the device

Applying the programming

head

The programming head (PGH) features a diagram of the device. This is used to
assist in positioning the head to ensure proper telemetry.

• Make sure the PGH is positioned correctly.

Establishing telemetry

contact

The programmer (or the SafeSync Module) can be no less than 20 cm and no more
than 3 m from the device; ideally there should be no hindrances between the patient
and the programmer.

• Switch on RF telemetry on the programmer.

• Apply the programming head for about 2 s until successful initialization is
displayed on the programmer:

The SafeSync symbol is displayed in the navigator and the signal
strength is displayed in the status line.

• Remove the programming head.

Note: After auto-initialization, all parameters are activated as in the factory
settings.

Auto-initialization Auto-initialization begins automatically once the first connected lead is sensed.

Auto-initialization is terminated 10 minutes after connection of the first lead. If no
other program has been transferred in the meantime, the device subsequently
works with active automatic functions in the factory settings or with the preset
program of the user.

Manual setting of the lead polarity or measurement of lead impedances is not
necessary.

Behavior during

auto-initialization

• During transmission of a permanent program:
Auto-initialization is terminated and the transferred program is active.

• During testing:
Tests cannot be performed during auto-initialization; stop it beforehand. Auto-

initialization will not be continued upon completion of the test.

1 Disconnect stylets and stylet guides.
2 • Connect the unipolar or bipolar IS-1 lead connector ventricle to RV.

• Connect the unipolar or bipolar IS-1 lead connector atrium to A.

• Connect the unipolar or bipolar IS-1 lead connector ventricle to LV.

3 Push the lead connector into the header without bending the conductor until

the connector tip becomes visible behind the set screw block.

4 If the lead connector cannot be inserted completely, the set screw may be

protruding into the drill hole of the set screw block. Carefully loosen the set
screw without completely unscrewing it, so that it does not become tilted
upon retightening.

5 Use the screwdriver to perpendicularly pierce through the slitting in the

center of the silicone plug until it reaches the set screw.

6 Turn the set screw clockwise until the torque control starts (you will hear a

clicking sound).

7 Carefully withdraw the screwdriver without retracting the set screw.

• When the screwdriver is withdrawn, the silicone plug automatically seals
the lead connection safely.

17 Implantation

Precautionary Measures while Programming

Checking the device system • After auto-initialization, perform a follow-up to see if the device system is func-

tioning properly.

• Perform a pacing threshold test to determine the pacing threshold.

Performing standard tests
and monitoring the patient

Critical conditions can occur for the patient even during standard tests due to inad­equate parameter settings or interrupted telemetry.

• Ensure sufficient patient care even during tests.

• After the threshold test, check to determine whether the threshold is clinically
and technically justifiable.

• Continuously monitor the ECG and the patient's condition.

• Cancel testing if necessary.

Do not interrupt telemetry

during a treatment.

Disconnecting the SafeSync Module from the programmer can result in interfer­ence with or termination of the SafeSync wandless telemetry.

• Do not disconnect the SafeSync Module from the programmer.

• Do not take the Operation Module off the ICS 3000.

Cancelling telemetry Programmer interference or interrupted telemetry during performance of tempo-

rary programs (follow-up tests) can result in inadequate pacing of the patient. This
is the case if the programmer can no longer be operated due to a program error or
a defective touch screen and therefore the temporary program cannot be termi­nated. Under these circumstances, it is helpful to cancel telemetry, in which case
the device automatically switches to the permanent program.

• In the case of telemetry with PGH: lift the programming head by at least 30 cm.

• In the case of RF telemetry: switch off and reposition the programmer.

• Turn off possible sources of interference.

Avoiding critical

parameter settings

No modes and parameter combinations that pose a risk to the patient should be set.

• Prior to setting rate adaptation, determine the patient's capacity for strain.

• Check compatibility and effectiveness of parameter combinations after making
settings.

Manually setting

lead polarity

Due to the risk of an entrance/exit block, bipolar lead polarity (sensing/pacing)
should only be set if bipolar leads are implanted.

Setting triggered mode Triggered modes perform pacing regardless of intrinsic cardiac events. To prevent

undersensing due to electromagnetic interference in special cases, a triggered
mode can be displayed.

Setting sensing Manually set parameters can be unsafe. For example, unsuitable far-field protec-

tion may impede sensing of intrinsic pulses.

• Use automatic sensitivity control.

Setting the sensitivity A value set to < 2.5 mV/unipolar for device sensitivity may result in noise caused by

electromagnetic fields.

• Therefore, it is recommended that a value of ≥ 2.5 mV/unipolar be set according
to paragraph 28.22.1 of the EN

45502-2-1 standard. Setting sensitivity values

<

2.5 mV/unipolar requires explicit clinical need. Values like this can only be set

and retained with physician supervision.

18 Implantation

Preventing device-induced

complications

BIOTRONIK devices are equipped with several functions to prevent device-induced
complications to the greatest extent possible:

• Measure the retrograde conduction time.

• If the function is not yet automatically set: activate PMT protection.

• Set the VA criterion.

Preventing conduction

of atrial tachycardia

BIOTRONIK devices are equipped with several functions to prevent conduction of
atrial tachycardia to the ventricle(s):

•Set Mode Switching for indicated patients.

• Set the upper rate and the refractory periods to prevent abrupt ventricular rate
switching.

• Prefer Wenckebach response and avoid 2:1 behavior.

• Set all parameters so as to prevent constant changing between atrial and
ventricular-controlled modes.

Phrenic nerve stimulation
that cannot be terminated

With LV pacing, chronic phrenic nerve stimulation can in rare cases not be termi­nated by reprogramming the available left ventricular pacing configurations or by
other measures.

• Possibly set a right ventricular mode both in the permanent program and for
Mode

Switching.

Avoiding risks in the case

of exclusive LV pacing

Lead dislodgement in the case of exclusive left ventricular pacing could pose the
following risks: loss of ventricular pacing as well as induction of atrial arrhythmia.

• Consider sensing and pacing parameters with reference to loss of therapy.

• Exclusive LV pacing is not recommended for patients who depend on the device.

• Take possible interruption of automatic Active Capture Control into consider­ation.

• In the case of follow-ups and threshold tests, take loss of synchronized ventric­ular pacing into consideration.

• Mode Switching does not allow exclusive LV pacing; consider the consequences
when setting Mode Switching parameters.

If an ICD is implanted at

the same time, do not

permit unipolar pacing

If an ICD is implanted in addition to a pacemaker and a lead failure occurs, it is
possible to switch to unipolar pacing after resetting the pacemaker or using the
automatic lead check. As a result, the ICD could falsely inhibit or trigger tachyar­rhythmia therapy activity.

• Unipolar leads are not permitted in this configuration.

Recognizing lead failure Automatic impedance measurement is always switched on.

• Impedance values that indicate technical failure of a lead are documented in the
event list.

Consider power

consumption and service

time

The pacemaker permits programming of high pulse amplitudes with long pulse
widths at high rates to be able to adequately treat even rare diagnoses. In combina­tion with low lead impedance, this results in a very high level of power consumption.

• When programming large parameter values, take into account that the battery
depletion indicator ERI will be reached very early because the service time of the
battery may be reduced to less than 1

year.

• Home Monitoring ON reduces the service time by 3 months approximately.

RF telemetry requires somewhat more power: More frequent use of RF telemetry
than assumed during service time calculation (20 min per year) reduces the service
time by about 7 days for the SR(-T), 6 days for the DR(-T), and 5 days for the HF-T
device.

• Do not establish unnecessary RF telemetry.

•After 5 minutes without input, SafeSync switches to the economy mode.

• Check the battery capacity of the device at regular intervals.

19 Implantation

Magnet Response

Programming head

application

When the programming head is applied, time remains for device interrogation
before the device switches back to the previously set permanent therapy mode. The
same applies to programming head application to establish RF telemetry contact.

Magnet response in

standard program

Applying a magnet or the programming head can result in an unphysiological
rhythm change and asynchronous pacing. The magnet response is set as follows in
the standard program of BIOTRONIK pacemakers:

• Asynchronous:
For the duration of the magnet application – mode D00 (possibly V00 / A00)

without rate adaptation;
Magnet rate: 90 bpm

•Automatic:
For 10 cycles – mode D00, subsequently mode DDD without rate adapta

tion;

Magnet rate: 10 cycles with 90 bpm, subsequently set basic rate

• Synchronous:

Note: See also the replacement indication information.

Mode DDD (where applicable: VVI) without rate adaptation;
Magnet rate: set basic rate

Magnet response with ERI After reaching ERI, pacing is performed as follows after applying the magnet or

programming head:

Magnet application

by patients

If patients are performing their own magnet application, the synchronous magnet
response has to have been programmed. Patients should also know the following:

• When may the magnet be used?
In cases of severe dizziness and indisposition.

• How long is the magnet placed on the pacemaker?
1 to 2 s.

• What happens when the magnet is applied?
The IEGM of the last 10 seconds is stored.

• What has to happen after magnet application?
The patient has to contact the physician for a follow-up.

Magnet
response

Cycles 1 to 10 After 10th cyle

Automatic Asynchronous with 80 bpm Synchronous with basic rate

reduced by 4.5 to 11%
Asynchronous Asynchronous with 80 bpm Asynchronous with 80 bpm
Synchronous Synchronous with basic rate

reduced by 4.5 to 11%

Synchronous with basic rate

reduced by 4.5 to 11%

20 Implantation

Follow-up

Follow-up intervals Follow-ups must be performed at regular, agreed intervals.

• Following the lead ingrowth phase, approximately 3 months after implantation,
the first follow-up should be carried out by the physician using the programmer
(in-office follow-up).

• The next in-office follow-up should be carried out once a year and no later than
12 months after the last in-office follow-up.

Follow-up with BIOTRONIK

Home Monitoring

®

Monitoring using the Home Monitoring function does not serve to replace regular
in-office appointments with the physician required for other medical reasons.

Follow-up supported by Home Monitoring can be used to functionally replace in­office follow-up under the following conditions:

• The patient was informed that the physician must be contacted if symptoms
worsen or if new symptoms arise despite the use of the Home

Monitoring func-

tion.

• Device messages are transmitted regularly.

• The physician decides whether the data transmitted via Home Monitoring with
regard to the patient's clinical condition as well as the technical state of the
device system are sufficient. If not, an in-office follow-up has to be carried out.

Possible early detection due to information gained via Home Monitoring may neces­sitate an additional in-office follow-up. For example, the data may indicate at an
early stage lead problems or a foreseeable end of service time (ERI). Furthermore,
the data could provide indications of previously unrecognized arrhythmias or modi­fication of therapy by reprogramming the device.

Follow-up with the

programmer

Use the following procedure for in-house follow-up:

Patient Information

Patient ID card A patient ID card is included in delivery.

• Provide the patient with the patient ID card.

• Request that patients contact the physician in case of uncertainties.

Prohibitive signs Premises with prohibitive signs must be avoided.

• Draw the patient's attention to prohibitory signs.

Possible sources of

interference

Electromagnetic interference should be avoided in daily activities. Sources of inter­ference should not be brought into close proximity with the device.

• Draw the patient's attention to special household appliances, security check­points, anti-theft alarm systems, strong electromagnetic fields, cell phones,
and transmitters among other things.

• Request patients to do the following:
— Use cell phones on the opposite side of their body from the device.

— Keep the cell phone at least 15 cm away from the device both during use and

when stowing.

1 Record and evaluate the ECG.
2 Interrogate the device.
3 Evaluate the status and automatically measured follow-up data.
4 Check the sensing and pacing functions.
5 Possibly evaluate statistics and IEGM recordings.
6 Manually perform standard tests if necessary.
7 Possibly customize program functions and parameters.
8 Transmit the program permanently to the device.
9 Print and document follow-up data (print report).

10 Finish the follow-up for this patient.

21 Implantation

Replacement Indications

Possible battery levels The time span from the beginning of service (BOS) to elective replacement indica-

tion (ERI) is determined by, among others, the following:

• Battery capacity

• Lead impedance

• Pacing program

• Pacing to inhibition ratio

• Pacemaker circuit properties

The following are the defined pacemaker operational statuses:

ERI activation ERI detection is automatically activated after the following events:

• Successful auto-initialization

• Storage for longer than 24 months

ERI display ERI is displayed as follows:

• On the programmer after interrogation of the pacemaker

• By a defined decrease in the basic rate as well as the magnet rate

Change of the mode

with ERI

This change depends on the mode which is set. It is displayed on the programmer.

• Single-chamber modes: VVI

• Double-chamber modes: VDD

• Triple-chamber modes: Double-chamber pacing, one biventricular setting is
kept

Deactivated functions

with ERI

The following functions are deactivated:

• Atrial pacing

• Night program

• Rate adaptation

• Atrial and ventricular capture control

• Rate fading

• Atrial overdrive pacing

• IEGM recordings

• Statistics

• Home Monitoring

• Rate hysteresis

• Ventricular pacing suppression

Rate decrease The decrease of basic rate and magnet rate is defined as follows:

• In the following modes, the pacing rate decreases by 11%:
DDD(R); DDT(R); D00(R); VDD(R); VDI(R); VVI(R); VVT(R); AAI(R); AAT(R); A00(R)

• In the modes DDI(R) and DVI(R), only the VA interval is extended by 11%. This
reduces the pacing rate by 4.5 to 11%, depending on the configured AV delay.

BOS Beginning of service Battery is in good condition; normal

follow-up.

ERI Elective replacement 

indication

The replacement time has been reached.
The pacemaker must be replaced.

EOS End of service End of service time with regular pace-

maker activity

22 Implantation

Expected service time

after ERI

• The information is based on a lead impedance of 500 Ω at 100% pacing and the
data of the battery manufacturer.

• Parameter with high pacing energy:
110 bpm; 4.6 V; 1.5 ms; 500 Ω

• Parameters with low pacing energy:
30 bpm; 0.2 V; 0.1 ms; 500 Ω

• Interval between ERI and EOS for the single-chamber device in AAI(R)/VVI(R)
mode, for the double and triple chamber device in DDD(R) mode, in standard
program and with both high and low pacing energy:

— Mean value: 8 months
— Minimum value: 6 months

Explantation and Device Replacement

Explantation • Disconnect the leads from the header.

• Remove the device and, if necessary, leads using state-of-the-art technology.

• Explants are biologically contaminated and must be disposed of safely due to
risk of infection.

Device replacement The following applies to leads from a previous device that are intended for further

use:

• Check the leads prior to connecting to the new device.

If, upon replacing the device, already implanted leads are no longer used but left in
the patient, then an additional uncontrolled current path to the heart can result.

• Insulate connections that are not used.

Basic principles:

• The device must not be resterilized and reused.

Cremation Devices should not be cremated.

• Explant the device before the cremation of a deceased patient.

Disposal BIOTRONIK takes back used products for the purpose of environmentally safe

disposal.

• Clean the explant with a solution of at least 1% sodium hypochlorite.

• Rinse with water.

• Fill out explantation form and send to BIOTRONIK together with the cleaned
device.

23 Parameters

4 Parameters

Parameters4403587Technical ManualEluna SR(-T), DR(-T), HF(-T)

Timing

Basic rate day/night

Rate hysteresises

AV delay

AV hystereses

Parameter Range of values Standard SR DR HF

Basic rate 30 ... (5) ... 100 ... (10) ... 200 bpm 60 bpm x x

50 bpm x

Night rate OFF; 30 ... (5) ... 100 ... (10)

... 190 bpm

OFF x x x

Night
begins

00:00 ... (10 min) ... 11:50 PM hh:mm 22:00 hh:mm x x x

Night ends 00:00 ... (10 min) ... 11:50 PM hh:mm 06:00 hh:mm x x x

Parameter Range of values Standard SR DR HF

Hysteresis OFF;

-5 ... (-5) ... -25 ... (-20)
... -65 bpm

OFF x x x

Repetitive / search
cycles

OFF; ON OFF x x x

Parameter Range of values Standard SR DR HF

AV delay Low; Medium; High; Fixed;

Individual

Low x x

20 ... (5) ... 350 ms
(in 6 rate ranges)

180-170­160-150­140 ms

x

150-140­130-120 ms

x

Sense compensation OFF; -10 ... (-5) ... -120 ms -45 ms x x
AV safety interval 100 ms 100 ms x x

Parameter Range of values Standard SR DR HF

AV hysteresis mode OFF; Positive; Negative

HF in RV modes: IRSplus

OFF x x

Positive modes: 
AV hysteresis

70; 110; 150; 200 ms 70 ms

CLS modes:
110 ms

xx

Negative modes: 
AV hysteresis

10 ... (10) ... 150 ms 50 ms x x

AV repetetive / scan
cyles

ON; OFF ON x x

24 Parameters

Ventricular pacing

Upper rate

Mode switching

Ventricular pacing

suppression

Parameters valid for devices in DDD-ADI or DDDR-ADIR modes:

Parameter Range of values Standard SR DR HF

Ventricular pacing BiV BiV x
Triggering OFF; RVs; RVs + PVC RVs x
LV T-wave protection ON; OFF ON x
Maximum 

trigger rate

AUTO; 
90 ... (10) ... 160 bpm

AUTO x

Initially paced
chamber

RV; LV LV x

VV delay after Vp 0 ... (5) ... 80 ... (10) ... 100 ms 0 ms x
VV delay after sense 0 ms 0 ms x

Parameter Range of values Standard SR DR HF

Upper rate
SR: in VVT mode

90 ... (10) ... 200 bpm 130 bpm x x x

Wenckebach response Automatically set — x x
Atrial upper rate OFF;

175; 200; 240 bpm

240 bpm x x

Parameter Range of values Standard SR DR HF

Mode switching OFF; ON ON x x
Intervention rate 100 ... (10) ... 250 bpm 160 bpm x x
Switch to (mode) DDI; DDI(R) when

permanent DDD(R)
VDI; VDI(R) when
permanent VDD(R)

DDI(R)
VDI(R)

xx

Ventricular pacing RV; BiV BiV x
Onset criterion 3 ... (1) ... 8 5 x x
Resolution criterion 3 ... (1) ... 8 5 x x
Change of the basic rate

with mode switching

OFF; +5 ... (5) ...
+30 bpm

+10 bpm x x

Rate stabilization 
with mode switching

OFF; ON OFF x x

2:1 lock-in protection OFF; ON DR: ON

HF: only
when RV
modes ON

xx

Parameter Range of values Standard SR DR HF

Vp suppression ON; OFF OFF x x
Pacing suppression 

after consecutive Vs

1 ... (1) ... 8 6 x x

Pacing supported 
after X-out-of-8 cycles

1; 2; 3; 4 3 x x

25 Parameters

Refractory periods

Blanking periods

PMT protection

Pacing and Sensing

Pulse amplitude

and pulse width

Sensitivity

Parameter Range of values Standard SR DR HF

Refractory period 200 ... (25) ... 500 ms 250 ms x
Atrial refractory

period

AUTO AUTO x x

Atrial refractory
period in the modes
AAI(R); AAT(R); DDT

300 ... (25) ... 775 ms 350 ms x x

AUTO PVARP ON; OFF ON x x
PVARP Auto PVARP OFF:

175 ... (25) ... 600 ms

Auto PVARP ON:
Automatically set

xx

PVARP after PVC PVARP + 150 ms

(max: 600 ms) is auto­matically programmed

400 ms x x

Right ventricular
refractory period

200 ... (25) ... 500 ms 250 ms x x

Left ventricular
refractory period

200 ms 200 ms x

Parameter Range of values Standard SR DR HF

Far-field protection
after Vs

100 ... (10) ... 220 ms 100 ms x x

Far-field protection
after Vp

100 ... (10) ... 220 ms 150 ms x x

Ventricular blanking
period after Ap

30 ... (5) ... 70 ms 30 ms x x

Parameter Range of values Standard SR DR HF

PMT protection OFF; ON ON x x
VA criterion 250 ... (25) ... 500 ms 350 ms x x

Parameter Range of values Standard SR DR HF

Pulse amplitude A/
RV/LV

0.2 ... (0.2) ... 6.0 ... (0.5)
... 7.5 V

3.0 V x x x

Pulse width A/RV/LV 0,1 ...(0,1) ... 0.5 ... (0.25)

... 1.5 ms

0.4 ms x x x

Parameter Range of values Standard SR DR HF

Sensitivity AUTO; 1.5 ... (0.5) ... 7.5 mV AUTO x
Sensitivity A AUTO; 0.1 ... (0.1) ... 1.5 

... (0.5) ... 7.5 mV

AUTO x x

RV sensitivity AUTO; 0.5 ... (0.5) ... 7.5 mV AUTO x x
LV sensitivity OFF; AUTO; 0.5 ... (0.5) 

... 7.5 mV

AUTO x

26 Parameters

Atrial capture control

Ventricular capture control

Atrial overdrive pacing

Lead configuration

Parameter Range of values Standard SR DR HF

Atrial capture control ATM (monitoring only);

ON; OFF

ON x x

Minimum amplitude 0.5 ... (0.1) ... 4.8 V 1.0 V x x
Threshold test start 2.4 ... (0.6) ... 4.8 V 3.0 V x x
Safety margin 0.5 ... (0.1) ... 1.2 V 1.0 V x x
Search type Interval; time of day Time of day x x
Interval 0.1; 0.3; 1; 3; 6; 12; 24 h 24 h x x
Time of day 00:00 ... (10 min) ... 23:50 2:00 AM hh:mm x x

Parameter Range of values Standard SR DR HF

Ventricular capture
control RV, LV

ATM (monitoring only);
ON; OFF

ON x x

Minimum amplitude 0.7 V 0.7 V x x
Threshold test start 2.4 ... (0.6) ... 4.8 V 3.0 V x x
RV safety margin 0.3 ... (0.1) ... 1.2 V 0.5 V x x
LV safety margin 1.0; 1.2 V 1.0 V x
Search type Interval; time of day Time of day x x
Interval 0.1; 0.3; 1; 3; 6; 12; 24 h 24 h x x
Time of day 00:00 ... (00:10)

... 23:50 hh:mm

00:30 hh:mm x x

Parameter Range of values Standard SR DR HF

Atrial overdrive
pacing

ON; OFF
With ON: maximum overpacing
rate 120 bpm, mean rate
increase approximately 8 bpm,
rate decrease after 20 cycles

OFF x x

Parameter Range of values Standard SR DR HF

Sensing polarity A Unipolar, Bipolar Unipolar x x
Sensing polarity RV Unipolar, Bipolar Unipolar x x x
Sensing polarity LV Unipolar, Bipolar Unipolar x
Pacing polarity A Unipolar, Bipolar Unipolar x x
Pacing polarity RV Unipolar, Bipolar Unipolar x x x
Pacing polarity LV LV tip -> LV ring

LV tip -> RV ring
LV ring -> LV tip
LV ring -> RV ring
LV tip -> housing
LV ring -> housing

LV tip –>
housing

x

27 Parameters

IEGM recordings

Rates for statistics

Rate Adaptation

CLS modes: closed loop

stimulation

Parameters valid for 8 series devices:

R modes: Accelerometer

Parameter Range of values Standard SR DR HF

IEGM recordings 8 series:

20 (quantity); each max. 10 s
6 series:
12 (quantity); each max. 10 s

—xxx

Types of IEGM
recordings

High atrial rate (HAR) HAR x x x
Mode switching x x x
High ventricular rate (HVR) ON x x x
8 series:

Patient triggering (triggered
by patient)

OFF x x x

Pre-trigger
recording

0; 25; 50; 75; 100% 75 % x x x

IEGM signal Filtered; Unfiltered Filtered x x x

Parameter Range of values Standard SR DR HF

High atrial rate: 
HAR limit

100 ... (5) ... 250 bpm 200 bpm x x

High ventricular rate:
HVR limit

150 ... (5) ... 200 bpm 180 bpm x x x

HVR counter 4; 8; 12; 16 cycles 8 cycles x x x
Start resting period 00:00 ... (00:10) ...

23:50 hh:mm

02:00 hh:mmxxx

Duration of resting
period

00:30 ... (00:30) ... 12:00
hh:mm

04:00
hh:mm

xxx

Enable lead check ON; OFF ON x x x

Parameter Range of values Standard SR DR HF

Maximum CLS rate 80 ... (5) ... 160 bpm 120 bpm x x x
CLS response Very low; Low; Medium;

High; Very high

Medium x x x

CLS resting rate
control

OFF; +10 ... (10) ... +50 bpm +20 bpm x x x

Vp required Yes; No No

BiV modes:
Yes

xxx

Parameter Range of values Standard SR DR HF

Sensor gain AUTO; Very low; Low;

Medium; High; Very high

AUTO x x x

Max. sensor rate 80 ... (5) ... 180 bpm 120 bpm x x x
Sensor threshold Very low; Low; Medium;

High; Very high

Medium x x x

Rate fading OFF; ON OFF x x x
Rate increase 1; 2; 4; 8 bpm/cycle 2 bpm/cycle x x x
Rate decrease 0.1; 0.2; 0.5; 1.0 bpm/cycle 0.5 bpm/

cycle

xxx

28 Parameters

MRI Program

MRI modes Modes valid for devices marked ProMRI

MRI parameters Preset parameters in the MRI program:

Preset Programs

Standard and safe program Mode after auto-initialization:

Lead configuration, determined and set immediately after connection (auto lead
check)

Parameters after auto-initialization:

Mode Range of values Standard SR DR HF

MRI Program ON; OFF OFF x x x
MRI mode OFF; A00; V00 — x

OFF; D00; A00; V00 — x
OFF; D00; A00; V00;

D00-BiV; V00-BiV

—x

Parameter Range of values Standard SR DR HF

Basic rate 70 ... (10) ... 160 bpm — x x x
AV delay 110 ms — x x
Pulse amplitude A/RV4.8 V — x x x

Pulse width A/RV 1.0 ms
Pulse amplitude LV As in permanent program — x
Pulse width LV
VV delay 0 ms — x

Parameter Factory

settings

Standard
program

Safe program SR DR HF

Mode VVI VVIR VVI

In the AAI mode, the
safe program is also
AAI.

x

Mode DDD DDDR VVI x x

Parameter Factory

settings

Standard
program

Safe
program

SR DR HF

Pacing polarity A/RV Unipolar Unipolar Unipolar x x x
Pacing polarity LV TCUP TCUP TCUP x
Sensing polarity A/RV Unipolar Unipolar Unipolar x x x
Sensing polarity LV Unipolar Unipolar Unipolar x
Automatic lead check ON ON — x x x

Parameter Factory

settings

Standard
program

Safe
program

SR DR HF

Basic rate 60 bpm 60 bpm 70 bpm x x

50 bpm x
Night program OFF OFF OFF x x x
Rate hysteresis OFF OFF OFF x x x
Upper rate 130 bpm 130 bpm — x x
Dynamic AV delay Low Low — x x

29 Parameters

AV hysteresis OFF OFF — x x
Sense compensation -45 ms -45 ms — x x
AV safety delay 100 ms 100 ms — x x
VV delay 0 0 0 x
LV T-wave protection ON ON ON x
Far-field protection

after Vs

100 ms 100 ms — x x

Far-field protection
after Vp

150 ms 150 ms — x x

Ventricular blanking period
after Ap

30 ms 30 ms — x x

PMT protection ON ON — x x
VA criterion 350 ms 350 ms — x x
Magnet response AUTO AUTO AUTO x x x
Pulse amplitude A 3.0 V 3.0 V — x x
Pulse amplitude RV 3.0 V 3.0 V 4.8 V x x x
Pulse amplitude LV 3.0 V 3.0 V 4.8 V x
Pulse width A 0.4 ms 0.4 ms — x x
Pulse width RV 0.4 ms 0.4 ms 1.0 ms x x x
Pulse width LV 0.4 ms 0.4 ms 1.0 ms x
Sensitivity A AUTOAUTO— xx
Sensitivity RV AUTO AUTO 2.5 mV x x x
Sensitivity LV AUTO AUTO 2.5 mV x
Refractory period A AUTO AUTO — x x
Refractory period RV 250 ms 250 ms 300 ms x x x
Refractory period LV 200 ms 200 ms 200 ms x
Mode switching ON ON — x x
Onset criterion 5-out-of 8 5-out-of 8 — x x
Resolution criterion 5-out-of 8 5-out-of 8 — x x
Intervention rate 160 bpm 160 bpm — x x
Switches to DDIR DDIR — x x
The basic rate with mode

switching

+10 bpm +10 bpm — x x

Rate stabilization with
mode switching

OFF OFF — x x

PVARP AUTO

(Start

250 ms)

AUTO
(Start
250 ms)

—xx

PVARP after PVC 400 ms 400 ms — x x
Capture control A ON ON OFF x x x
Capture control RV ON ON OFF x x
Capture control LV ON ON OFF x
Atrial overdrive pacing OFF OFF — x x
Vp suppression OFF OFF — x
IEGM recording (HAR, HVR) ON ON OFF x x x
Home Monitoring OFF OFF OFF x x x

Parameter Factory

settings

Standard
program

Safe
program

SR DR HF

30 Parameters

Tolerances of Parameter Values

Parameter Range of values Tolerance

Basic rate 30 ... (5) ... 100 ...

(10) ... 200 bpm

± 20 ms

Basic interval 1000 ms ± 20 ms
Magnet rate (magnet interval) 90 bpm (664 ms) ± 20 ms
Pulse amplitude 0.3 ... 7.5 V The greater value of

±50 mV
or +20/-25%

Pulse width 0.1 ... 0.4 ms ± 0.04 ms

0.5 ... 1.0 ms ± 0.10 ms

1.25 ... 1.5 ms ± 0.15 ms

Sensitivity A
EN 45502-2-1 triangle pulse

0.1 ... 0.2 mV ±0,05 mV

0.3 ... 7.5 mV ±20%

RV/LV sensitivity
EN 45502-2-1 triangle pulse

0.5 ... 7.5 mV ±50%

Refractory period 200 ... 500 ms + 10/-30 ms
Maximum activity rate 80 ... 180 bpm ± 20 ms
Lead impedance 100 ... 200 Ω ±50 Ω

201 ... 2500 Ω ±25%

31 Technical Data

5 Technical Data

Technical Data5403587Technical ManualEluna SR(-T), DR(-T), HF(-T)

Mechanical Characteristics

Note: D = housing without header

Measurements

for the housing

X-ray identification BIO SF

Materials in contact

with body tissue

• Housing: titanium

• Header: epoxy resin

• Plugs in the header: silicone

Electrical Characteristics

Electrically conductive

surface

The device housing has the form of a flattened ellipsoid. The electrically conductive
area is 33 cm

2

.

Components and

input values

Electrical characteristics determined at 37°C, 500 Ω:

Telemetry data • Nominal carrier frequency: 403.62 MHz

• Maximum power of transmission: < 25 µW (–16 dBm)

Pulse form The pacing pulse has the following form:

The pulse amplitude reaches its maximum
value at the beginning of the pulse (Ua). With
increasing pacing duration (tb), the pulse
amplitude is reduced dependent on the pacing
impedance.

Resistance to interference All variants of BIOTRONIK devices comply with the requirements of 

prEN 45502-2-1: 2006, § 27.5.1 at the highest sensitivity.

Device W x H x D [mm] Volume [cm3] Mass [g]

Single-chamber SR(-T) 53 x 39 x 6.5 11 24
Dual-chamber DR(-T) 53 x 44.5 x 6.5 12 25
Triple-chamber HF-T 53 x 49 x 6.5 14 27

Circuit Hybrid electronics with VLSI-CMOS chip
Input impedance > 10 kΩ
Pulse form Biphasic, asymmetric
Polarity Cathodic

32 Technical Data

Battery Data

Battery characteristics The following data is provided by the manufacturers:

Shortening of the service

time after long storage

period

Depending on the storage period, the service time from the beginning of service
BOS to the replacement time ERI decreases as follows:

•After 1 year by three months

• After 1.5 years by four months

Power consumption • BOS, inhibited: SR(-T), DR(-T) 6 µA; HF-T: 7 µA

• BOS, 100% pacing: SR(-T) 9 µA; DR(-T) 14 µA; HF-T: 18 µA

Calculation of service times Mean service times are valid for devices with and without Home Monitoring; they

are pre-estimated from the following and other data:

• Technical data of the battery manufacturer:

• Basic rate of 60 bpm in AAIR/VVIR modes (single-chamber devices) or DDDR
modes (dual-chamber and triple-chamber devices)

•Home Monitoring configuration: OFF

• With 10-minute RF telemetry twice a year as well as without RF telemetry

• Configuration of different pulse amplitudes and lead impedances

Mean service times SR(-T) For single-chamber devices, the following times (in years) result:

Using RF telemetry:

Manufacturer LITRONIK GmbH, 01796 Pirna,

Germany

Battery type LiS 3150M
System LiMn0

2

Device type SR(-T); DR(-T); HF-T
Battery voltage at BOS 3.1 V
Open-circuit voltage 3.1 V
Nominal capacity 1.2 Ah
Remaining capacity at ERI 0.2 Ah
Usable capacity until EOS 1.0 Ah

Amplitude Impedance [Ω] Pacing

10% 50% 100%

1.5 V 500 14.7 14.4 13.8
1000 14.9 14.8 14.4

2.5 V 500 14.1 13.5 11.8
1000 14.5 14.2 13.1

3.0 V 500 13.5 13.1 10.8
1000 14.2 13.6 12.4

3.5 V 500 13.1 12.8 10.1
1000 13.9 13.3 11.8

5.0 V 500 10.4 8.7 6.2
1000 12.1 10.8 8.3

33 Technical Data

Without using RF telemetry:

Mean service times DR(-T) For dual-chamber devices, the following times (in years) result:

Using RF telemetry:

Without using RF telemetry:

Amplitude Impedance [Ω] Pacing

10% 50% 100%

1.5 V 500 >15 >15 >15
1000 >15 >15 >15

2.5 V 500 >15 >15 13.3
1000 >15 >15 >15

3.0 V 500 >15 14.2 11.2
1000 >15 >15 14.1

3.5 V 500 14.9 12.9 10.1
1000 >15 >15 12.9

5.0 V 500 11.3 9.1 6.2
1000 14.5 12.5 9.4

Amplitude Impedance [Ω] Pacing

10% 50% 100%

1.5 V 500 12.7 12.3 11.4
1000 12.9 12.8 12.2

2.5 V 500 11.8 11.0 8.9
1000 12.4 11.9 10.4

3.0 V 500 11.0 9.9 7.9
1000 11.9 11.2 9.7

3.5 V 500 10.5 9.3 7.1
1000 11.6 10.7 8.9

5.0 V 500 7.5 5.8 3.8
1000 9.3 7.8 5.5

Amplitude Impedance [Ω] Pacing

10% 50% 100%

1.5 V 500 >15 14.8 13.0
1000 >15 >15 14.7

2.5 V 500 13.6 12.1 9.4
1000 >15 14.1 12.0

3.0 V 500 12.1 10.2 7.9
1000 14.2 12.7 10.1

3.5 V 500 11.1 9.3 7.1
1000 13.4 11.7 8.9

5.0 V 500 7.8 5.8 3.8
1000 10.7 8.7 5.9

34 Technical Data

Mean service times HF-T For triple-chamber devices, the following times (in years) result:

Using RF telemetry:

Without using RF telemetry:

Pulse width:

0.4 ms

Amplitude:

Pacing Impedance:
atrial + biven-

tricular 100%

A+RV+LV:
500 Ω

A+RV:
500 Ω
LV: 800 Ω

A+RV+LV:
1000 Ω

A: 2.5 V
RV: 2.5 V
LV: 3.5 V

0% 7.8 8.4 9.3
30% 7.5 8.1 9.1
50% 7.3 7.9 8.9
100% 6.9 7.5 8.6

A: 2.5 V
RV: 2.5 V
LV: 2.5 V

0% 8.9 9.4 10.3
30% 8.6 9.0 9.9
50% 8.3 8.8 9.8
100% 7.8 8.2 9.3

A: 3.5 V
RV: 3.5 V
LV: 5 V

0% 4.8 5.7 6.6
30% 4.6 5.3 6.3
50% 4.5 5.2 6.2
100% 4.2 4.8 5.8

A: 2.0 V
RV: 2.2 V
LV: 2.4 V

0% 9.1 9.5 10.3
30% 8.8 9.2 10.0
50% 8.6 8.9 9.9
100% 8.1 8.4 9.6

A: 3.0 V
RV: 3.0 V
LV: 3.0 V

0% 7.6 8.1 9.2
30% 7.2 7.6 8.8
50% 6.9 7.3 8.6
100% 6.3 6.7 8.1

Pulse width:

0.4 ms

Amplitude:

Pacing Impedance:
atrial + biven-

tricular 100%

A+RV+LV:
500 Ω

A+RV:
500 Ω
LV: 800 Ω

A+RV+LV:
1000 Ω

A: 2.0 V
RV: 2.2 V
LV: 2.4 V

0% 10.6 11.1 12.2
30% 10.2 10.8 11.9
50% 9.9 10.4 11.8
100% 9.4 9.8 11.3

A: 2.5 V
RV: 2.5 V
LV: 2.5 V

0% 10.3 10.8 12.0
30% 9.8 10.4 11.7
50% 9.6 10.1 11.4
100% 9.0 9.4 10.9

A: 2.5 V
RV: 2.5 V
LV: 3.5 V

0% 8.8 9.8 10.8
30% 8.5 9.3 10.6
50% 8.3 9.1 10.4
100% 7.8 8.6 10.0

A: 3.0 V
RV: 3.0 V
LV: 3.0 V

0% 8.8 9.4 10.8
30% 8.3 8.8 10.3
50% 7.9 8.5 10.1
100% 7.3 7.8 9.5

A: 3.5 V
RV: 3.5 V
LV: 5 V

0% 5.3 6.4 7.7
30% 5.1 6.1 7.3
50% 4.9 5.8 7.2
100% 4.6 5.3 6.8

35 Technical Data

Legend for the Label

The label icons symbolize the following:

Manufacturing date Use by

Storage temperature Order number

Serial number Product identification

number

CE mark

Contents Follow the instructions for

use

Sterilized with ethylene oxide

Do not resterilize Do not reuse

Do not use if packaging is
damaged

Non-sterile

Transmitter with non-ionizing radiation at designated
frequency

Label icon on devices
with ProMRI

®

:

MR conditional: Patients having a device system
implanted whose components are labeled with this
symbol on the packaging can be examined using an MR
scan under precisely defined conditions.

TP2 Compatibility with telemetry protocol version 2

of BIOTRONIK Home Monitoring

Example

Uncoated device: NBG code and
compatible leads

Example

Coated device: NBG code and compat­ible leads

Screwdriver

Example

Header

Bipolar IS-1 connector

Unipolar IS-1 connector

STERILIZE

2

NON

STERILE