Pumps, pain management and regional anaesthesia




Patient-controlled analgesia (PCA)


PCA represents one of the most significant advances in the treatment of postoperative pain. Improved technology enables pumps to accurately deliver boluses of opioid when a demand button is activated by the patient.


It is the patient who determines the plasma concentration of the opioid, this being a balance between the dose required to control the pain and that which causes side-effects. The plasma concentration of the opioid is maintained at a relatively constant level with the dose requirements being generally smaller.


Components




  • 1.

    It has a pump with an accuracy of at least ± 5% of the programmed dose ( Fig. 12.1 ).




    Fig. 12.1


    The Graseby Omnifuse PCA pump.


  • 2.

    The remote demand button is connected to the pump and activated by the patient.


  • 3.

    It has an anti-siphon and backflow valve.



Mechanism of action




  • 1.

    Different modes of analgesic administration can be employed:



    • a.

      patient-controlled, on-demand bolus administration


    • b.

      continuous background infusion and patient controlled bolus administration.



  • 2.

    The initial programming of the pump must be for the individual patient. The mode of administration, the amount of analgesic administered per bolus, the ‘lock-ouť time (i.e. the time period during which the patient is prevented from receiving another bolus despite activating the demand button), the duration of the administration of the bolus and the maximum amount of analgesic permitted per unit time are all variable settings on a PCA device.


  • 3.

    Some designs have the capability to be used as a PCA pump for a particular variable duration then switching automatically to a continuous infusion as programmed.


  • 4.

    The history of the drug administration including the total dose of the analgesic, the number of boluses and the number of successful and failed attempts can be displayed.


  • 5.

    The devices have memory capabilities so they retain their programming during syringe changing.


  • 6.

    Tamper-resistant features are included.


  • 7.

    Some designs have a safety measure where an accidental triggering of the device is usually prevented by the need for the patient to make two successive presses on the hand control within 1 second.


  • 8.

    PCA devices operate on main power sources or battery.


  • 9.

    Different routes of administration can be used for PCA, e.g. intravenous, intramuscular, subcutaneous or epidural routes.


  • 10.

    Alarms are included for malfunction, occlusion and disconnection.


  • 11.

    Ambulatory PCA pumps are available allowing patienťs mobilization during use ( Fig. 12.2 ).




    Fig. 12.2


    The CADD Legacy portable PCA.



Problems in practice and safety features




  • 1.

    The ability of the patient to cooperate and understand is essential.


  • 2.

    Availability of trained staff to programme the device and monitor the patient is vital.


  • 3.

    In the PCA mode, the patient may awaken in severe pain because no boluses were administered during sleep.


  • 4.

    Some PCA devices require special giving sets and syringes.


  • 5.

    Technical errors can be fatal.



Patient-controlled analgesia (PCA)





  • The patient has the ability to administer the opioid as required.



  • The device is programmed by the anaesthetist.



  • Different modes of administration.



  • Tamper-resistant designs are featured.



  • Ambulatory designs are available.



  • Technical errors can be fatal.




Syringe pumps


These are programmable pumps that can be adjusted to give variable rates of infusion and also bolus administration ( Fig. 12.3 ). They are used to maintain continuous infusions of analgesics (or other drugs). The type of flow is pulsatile continuous delivery and their accuracy is within ± 2–5%. Some designs can accept a variety of different size syringes. The power source can be battery and/or main power sources.




Fig. 12.3


The Graseby 2000 syringe pump.


It is important to prevent free flow from the syringe pump. Anti-siphon valves are usually used to achieve this. Inadvertent free flow can occur if the syringe barrel or plunger is not engaged firmly in the pump mechanism. The syringe should be securely clamped to the pump. Syringe drivers should not be positioned above the level of the patient. If the pump is more than 100 cm above the patient, a gravitational pressure can be generated that overcomes the friction between a non-secured plunger and barrel. Siphoning can also occur if there is a crack in the syringe allowing air to enter.


Some pumps have a ‘back-off’ function that prevents the pump from administering a bolus following an obstruction due to increased pressure in the system. An anti-reflux valve should be inserted in any other line that is connected to the infusion line. Anti-reflux valves prevent backflow up the secondary and often lower pressure line should a distal occlusion occur and they avoid a subsequent inadvertent bolus.


Volumetric pumps


These are programmable pumps designed to be used with specific giving set tubing ( Fig. 12.4 ). They are more suitable for infusions where accuracy of total volume is more important than precise flow rate. Their accuracy is generally within ± 5–10%. Volumetric pump accuracy is sensitive to the internal diameter of the giving set tubing. Various mechanisms of action exist. Peristaltic, cassette and reservoir systems are commonly used.




Fig. 12.4


The Graseby volumetric pump.


The power source can be battery and/or main power sources.


Target-controlled infusion pumps


These pumps have advanced software technology where the age and the weight of the patient are entered in addition to the drug’s desired plasma concentration. They are mainly used with a propofol and remifentanil infusion technique. The software is capable of estimating the plasma and effect (brain) concentrations allowing the anaesthetist to adjust the infusion rate accordingly.




Elastomeric pumps


These recently designed light, portable and disposable pumps allow continuous infusions of local anaesthetic solutions. Continuous incisional infiltration or nerve blocks can be used so allowing the delivery of continuous analgesia ( Fig. 12.5 ).




Fig. 12.5


The On-Q elastomeric pump. Note the flow restricter, bacterial filter, anti-syphon valve and the attached catheter.

(Courtesy Halyard.)


Components




  • 1.

    A small balloon-like pump is filled with local anaesthetic. Variable volumes of 100–600 mL are available.


  • 2.

    Specially designed catheters have lengths of 7–30 cm and of different gauges.


  • 3.

    It has a bacterial filter and a flow restrictor.



Mechanism of action




  • 1.

    The balloon deflates slowly and spontaneously delivering a set amount of local anaesthetic solution per hour. Rates of 2–14 mL/h can be programmed.


  • 2.

    Catheters are designed with multiple orifices allowing the infusion of local anaesthetic solution over a large area.


  • 3.

    An extra on-demand bolus facility is available in some designs. This allows boluses of 5 mL solution with a lock-out time of 60 minutes.


  • 4.

    Some designs allow the simultaneous infusion of two surgical sites.


  • 5.

    A silver-coated anti-microbial dressing is provided.



Problems in practice and safety features




  • 1.

    Some of the local anaesthetic may get absorbed into the balloon.


  • 2.

    The infusion rate profile can vary throughout the infusion. It is thought that the initial rate is higher than expected initially especially if the pump is under filled. The infusion rates tend to decrease over the infusion period.


  • 3.

    It is important to follow the manufacturer’s instructions regarding positioning of the device in relation to the body and ambient temperature. Changes in temperature can affect the flow rate. A change of 10°C in the temperature of water-based fluids results in altered viscosity, which causes a 20–30% change in flow rate.





Epidural needles


Epidural needles are used to identify and cannulate the epidural space. The Tuohy needle is widely used in the UK ( Fig. 12.6 ).




Fig. 12.6


18-G Tuohy needle. Note the 1-cm markings along its shaft.


Components




  • 1.

    The needle is 10 cm in length with a shaft of 8 cm (with 1-cm markings). A 15-cm version exists for obese patients.


  • 2.

    The needle wall is thin in order to allow a catheter to be inserted through it.


  • 3.

    The needle is provided with a stylet introducer to prevent occlusion of the lumen by a core of tissue as the needle is inserted.


  • 4.

    The bevel (called a Huber point) is designed to be slightly oblique at 20 degrees to the shaft, with a rather blunt leading edge.


  • 5.

    Some designs allow the wings at the hub to be added or removed.


  • 6.

    The commonly used gauges are either 16 G or 18 G.



Mechanism of action




  • 1.

    The markings on the needle enable the anaesthetist to determine the distance between the skin and the epidural space. Hence the length of the catheter left inside the epidural space can be estimated.


  • 2.

    The shape and design of the bevel ( Fig 12.7 ) enable the anaesthetist to direct the catheter within the epidural space (either in a cephalic or caudal direction).




    Fig. 12.7


    Detail of a spinal needle introduced through a Tuohy needle (top); an epidural catheter passing through a Tuohy needle (bottom).


  • 3.

    The bluntness of the bevel also minimizes the risk of accidental dural puncture.


  • 4.

    Some anaesthetists prefer winged epidural needles for better control and handling of the needle during insertion.


  • 5.

    A paediatric 19-G, 5-cm long Tuohy needle (with 0.5-cm markings), allowing the passage of a 21-G nylon catheter, is available.


  • 6.

    A combined spinal–epidural technique is possible using a 26-G spinal needle of about 12-cm length with a standard 16-G Tuohy needle. The Tuohy needle is first positioned in the epidural space then the spinal needle is introduced through it into the subarachnoid space (see Fig. 12.7 ). A relatively high pressure is required to inject through the spinal needle because of its small bore. This might lead to accidental displacement of the tip of the needle from the subarachnoid space leading to a failed or partial block. To prevent this happening, in some designs, the spinal needle is ‘anchored’ to the epidural needle to prevent displacement ( Fig. 12.8 ).




    Fig. 12.8


    The Portex CSEcure combined spinal–epidural device. The spinal needle (top); the epidural needle (middle); the spinal needle inserted and ‘anchored’ to the epidural needle (bottom).



Problems in practice and safety features




  • 1.

    During insertion of the catheter through the needle, if it is necessary to withdraw the catheter, the needle must be withdrawn simultaneously. This is because of the risk of the catheter being transected by the oblique bevel.


  • 2.

    In accidental dural puncture, there is a high incidence of postdural headache due to the epidural needle’s large bore (e.g. 16 G or 18 G).


  • 3.

    Wrong route errors: in order to avoid administering drugs that were intended for intravenous administration, all epidural bolus doses are performed using syringes, needles and other devices with safety connectors that cannot connect with intravenous Luer connectors.



Epidural needle





  • The most popular needle is the 10-cm Tuohy needle with the oblique bevel (Huber point). 5- and 15-cm-long needles also exist.



  • It has 1-cm markings to measure the depth of the epidural space.



  • A stylet introducer is provided with the needle.



  • A combined spinal–epidural technique is becoming more popular.






Epidural catheter, filter and loss of resistance device ( Fig. 12.9 )


The catheter


Components




  • 1.

    The catheter is a 90-cm transparent, malleable tube made of either nylon or Teflon and is biologically inert. The 16-G version has an external diameter of about 1 mm and an internal diameter of 0.55 mm.


  • 2.

    The distal end has two or three side ports with a closed and rounded tip in order to reduce the risk of vascular or dural puncture (see Fig. 12.7 ). Paediatric designs, 18 G or 19 G, have closer distal side ports.


  • 3.

    Some designs have an open end.


  • 4.

    The distal end of the catheter is marked clearly at 5-cm intervals, with additional 1-cm markings between 5 and 15 cm ( Fig. 12.10 ).




    Fig. 12.10


    Portex epidural catheter and filter. Note the markings up to 20 cm.


  • 5.

    The proximal end of the catheter is connected to a Luer lock and a filter (see Fig. 12.10 ).


  • 6.

    In order to prevent kinking, some designs incorporate a coil-reinforced catheter.


  • 7.

    Some designs are radio-opaque. These catheters tend to be more rigid than the normal design. They can be used in patients with chronic pain to ensure correct placement of the catheter.




Fig. 12.9


The Portex epidural set containing Tuohy needle, loss of resistance syringe and a range of other syringes and needles, epidural catheter and filter, drape, swabs and epidural catheter label.


Mechanism of action



Mar 2, 2019 | Posted by in ANESTHESIA | Comments Off on Pumps, pain management and regional anaesthesia

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