(acta anaesth. belg., 2012, 63, 147-167) post-cesarean ... · abstract: cesarean section patients...
TRANSCRIPT
© Acta Anæsthesiologica Belgica, 2012, 63, n° 4
Abstract : Cesarean section patients have compelling reasons to achieve optimal postoperative pain relief, be-cause they are expected to recover expeditiously and to care for their newborns within a few hours following sur-gery. Consequently, it is necessary that pain relief is safe and effective, that it does not interfere with the mother’s ability to care for her infant, and that it results in no ad-verse neonatal effects in breast-feeding women.However, although research in this field is increasing, there is no ‘gold standard’ for post-caesarean pain man-agement. Most methods rely on opioids, supplemented with non-opioid analgesics, nerve blocks or other adjunc-tive techniques.The aim of this manuscript is to evaluate and compare through literature review commonly used opioid- and non-opioid-based methods, when incorporated into a multimodal approach to post-caesarean pain manage-ment. Areas of promising research are also discussed.
Key words : Cesarean section ; cesarean delivery ; obstetrical anesthesia ; postoperative pain ; post- cesarean analgesia ; opioid analgesia ; spinal analgesia ; intra-thecal opioids ; epidural opioids ; patient-controlled analgesia ; systemic opioids ; nerve blocks ; wound infil-tration ; transversus abdominis plane block.
IntroductIon
Cesarean section is one of the most commonly performed surgical procedures. It is estimated that about 15% of births worldwide and 21.1% of those in western countries occur through a cesarean sec-tion (1). Over one million cesarean deliveries are thought to be carried out annually in the USA alone (2). The general advantages derived from re-lieving postoperative pain in surgical patients have been summarized elsewhere and apply also to wom-en undergoing cesarean delivery. However, cesare-an section patients have even more compelling rea-sons to beneficiate from optimal postoperative pain relief. Cesarean sections differ from other major laparotomies because women are expected to recov-er expeditiously and to care for their newborns within a few hours following surgery. Therefore, women after cesarean delivery are reluctant to feel drowsy, sleepy or restricted by equipment that does not allow them freely attending to their babies. Fur-
thermore, an ideal post-cesarean analgesic regimen must be cost-effective, simple to implement and with minimal impact on staff workload. Drug trans-fer into breast milk must also be minimal, with no adverse effects on the newborn. However, several other factors, including patient and anesthesiologist preferences, maternal medical situations such as pre-eclampsia or bleeding disorders, staff education and drug availability can influence the choice of the analgesic regimen. When questioning parturient women’s fears and expectations, pain during and after cesarean section is the greatest concern. This concern is immediately followed by vomiting, nau-sea, cramping, pruritus and shivering (3).
Post-cesarean pain consists of a somatic and visceral component (4). Visceral pain originates from uterine incision and contractions. The somatic component arises from nociceptors within the surgi-cal wound. Nerves supplying the anterior abdomi-nal wall are derived from T6 to L1 and pass through the plane between the layers of the transversus ab-dominis and internal oblique muscles (4).
The inherent inter-individual variability in the severity of postoperative pain is influenced by mul-tiple factors, such as individual sensitivity to pain, psychological factors (e.g., state of anxiety and so-matization), age and genetic factors (5 , 6). Ideally, the intensity of post-cesarean pain should be pre-dicted as to customize analgesia. Although the design of multifactorial predictive models for post-operative pain and analgesic requirement is still in its infancy, recent research has evidenced some im-portant predictors, including maternal expectations, anxiety and thermal and electrical pain threshold in the lower back near the dermatomes of the surgical wound (5, 6, 7).
(Acta Anaesth. Belg., 2012, 63, 147-167)
S. Verstraete ; M. Van de Velde.(*) Department of Anesthesiology, University Hospital
Leuven, Leuven, Belgium.Correspondence address : Sören Verstraete, Department of
Anesthesiology, University Hospital Leuven, Herestraat 49, 3000 Leuven. E-mail : [email protected]
Post-cesarean section analgesia
s. Verstraete (*) and M. Van de Velde (*)
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148 s. Verstraete and M. Van de Velde
ever, regional anesthesia has been increasingly used for both elective and emergency cesarean sec-tion (15). Controversy exists in the current literature regarding the preferable type of anesthesia. In one meta-analysis, the authors concluded that there was no evidence that regional anesthesia was superior to general anesthesia in terms of major maternal or neonatal complications. However, in that meta-analysis, the primary outcome of maternal and neo-natal death was omitted. Moreover, decreased blood loss was found in the regional technique group (16). Nevertheless, in another study, anesthesia-related maternal deaths that occurred between 1991 and 2002 in the United States were reviewed. Although case-fatality rates for general anesthesia are currently falling, the mortality risk ratio between general and regional anesthesia is still 1.7 (17).
Neuraxial opioids differ primarily in their po-tency, onset, duration of action and side effects (18, 19). The value of local anesthetic and opioid co-administration for post-cesarean pain control has been well documented. This combination allows reducing doses of both classes of drugs, thus lessen-ing the likelihood of adverse effects attributable to each (20, 21).
Intrathecal opioids
Spinal anesthesia is commonly used for cesarean section, and it has become a popular prac-tice to add opioids to the local anesthetic solution to enhance and prolong the intraoperative and post-operative analgesia. When administered in the sub-arachnoid space, they appear to act principally on µ-receptors in the substantia gelatinosa of the dorsal horn, by suppressing excitatory neuropeptide re-lease from the C fibers. Following intrathecal injec-tion, onset and duration of action are profoundly affected by the opioid’s pharmacokinetic behavior, and in particular, lipid solubility. Lipid-soluble compounds enjoy greater direct diffusion from the cerebrospinal fluid into the neural tissue. Fentanyl and sufentanil are, respectively, approximately 800 and 1600 times more soluble in lipids than mor-phine. Consequently, when administered neuraxial-ly, they will exhibit a faster onset, but also a shorter duration of action as compared with morphine (22, 23). Affinity for the µ-receptor is also important for determining the duration of analgesia. For instance, sufentanil, which is considerably more soluble in lipids than fentanyl, and therefore expected to be shorter-acting, has a longer duration of action (24).
Vascular reabsorption of opioids following in-trathecal administration does occur to some degree,
Chronic pain, which is defined as pain that per-sists beyond the usual course of an acute disease or after a reasonable time for healing (this period can vary from 2 to 6 months), is being recognized as a complication of cesarean delivery. One small sur-vey found that, 6 months after cesarean delivery, 12.3% of patients experience pain that is severe enough to affect infant care (8). In the same study, the incidence of persistent daily pain one year after cesarean section was 6%. Consequently, with mil-lions of cesarean sections annually worldwide, even a small prevalence of persistent pain carries impor-tant social and economic consequences.
Poorly controlled pain in the early post-opera-tive period may contribute to the generation of chronic pain (9, 10). Other strong predictors for per-sistent post-cesarean pain are previous chronic pain states and general anesthesia (8).
Chronic pain and postnatal depression (affect-ing 8-15% of postpartum women) commonly co-exist (11). In a multicenter, prospective, longitudi-nal cohort study in which 1288 women hospitalized for cesarean or vaginal delivery were enrolled, EIsenach et al. found a 2.5-fold increased risk of chronic pain and a 3-fold increased risk of postpar-tum depression among mothers with severe acute postpartum pain, independent of the type of deliv-ery (10).
In this review, we summarize the various drugs and techniques available for relieving acute pain af-ter cesarean delivery (see also Table 1).
MultIModal analgesIc therapy
Opioids are still playing a central role in post-cesarean pain management (12). From all published data, however, it is clear that opioids alone do not completely relieve pain after cesarean section (12). This finding emphasizes the importance of multi-modal or balanced analgesia, that is combining an-algesics of different classes or with different mecha-nisms of action. The aim of this approach is to improve analgesia and to decrease the amount of opioids that is needed to achieve pain relief, thus decreasing the incidence of opioid-related side ef-fects (13).
neuraxIal analgesIa
Both regional and general anesthesia are used for cesarean delivery, with different advantages and disadvantages (14). During the last decades how-
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© Acta Anæsthesiologica Belgica, 2012, 63, n° 4
post-cesarean sectIon analgesIa 149Ta
ble
1Su
mm
ary
tabl
eN
ote:
A m
ultim
odal
app
roac
h is
rec
omm
ende
d w
hene
ver
poss
ible
to m
axim
ize
pain
rel
ief w
hile
min
imiz
ing
unto
war
d ef
fect
sR
oute
Dru
gPr
o’s
Con
’sN
EUR
AX
IAL
INTR
ATH
ECA
LM
orph
ine
Gol
d st
anda
rdD
ose-
depe
nden
t pru
ritus
Cos
t-eff
ectiv
eD
ose-
inde
pend
ent P
ON
VU
rinar
y re
tent
ion
Ora
l her
pes
reac
tivat
ion
Res
pira
tory
dep
ress
ion
(usu
ally
del
ayed
due
to ro
stra
l spr
ead)
Dia
mor
phin
eQ
uick
er o
nset
and
incr
ease
d du
ratio
n of
act
ion
com
pare
d to
IT m
orph
ine
Prur
itus
and
vom
iting
at h
ighe
r dos
esFe
ntan
yl/S
ufen
tani
lEx
celle
nt in
traop
erat
ive
anal
gesi
aLi
ttle
post
oper
ativ
e an
alge
sic
bene
fitLo
wer
inci
denc
e of
PO
NV
and
del
ayed
resp
irato
ry d
epre
ssio
nM
eper
idin
e =
Pet
hidi
neC
an b
e us
ed in
pat
ient
s w
ith c
ontra
indi
catio
n to
loca
l ane
sthe
tics
Und
esira
ble
mot
or b
lock
ade
due
to lo
cal a
nest
hetic
pro
perti
esPO
NV
Nal
buph
ine
Mor
e fa
vora
ble
side
eff
ect p
rofil
e co
mpa
red
to IT
mor
phin
eLe
ss p
ain
cont
rol
Few
evi
denc
e in
lite
ratu
reC
loni
dine
(adj
unct
)Pr
olon
ged
post
oper
ativ
e an
alge
sia
Mild
ly in
crea
sed
intra
oper
ativ
e se
datio
nPo
stop
erat
ive
antih
yper
alge
sic
prop
ertie
sD
exm
edet
omid
ine
(adj
unct
)En
cour
agin
g re
sults
in lo
wer
abd
omin
al s
urge
ryN
o st
udie
s in
con
text
of c
esar
ean
deliv
ery
Neo
stig
min
e (a
djun
ct)
Red
uces
pos
tope
rativ
e m
orph
ine
requ
irem
ents
PON
VM
agne
sium
(adj
unct
)R
educ
es p
osto
pera
tive
mor
phin
e re
quire
men
tsM
ore
stud
ies
requ
ired
EPID
UR
AL
Mor
phin
eG
ood
post
oper
ativ
e an
alge
sia
Sim
ilar s
ide
effe
ct p
rofil
e as
IT m
orph
ine,
but
mor
e pr
uritu
sD
iam
orph
ine
Goo
d an
d pr
olon
ged
post
oper
ativ
e an
alge
sia
Nau
sea
is u
ncom
mon
Less
pru
ritus
com
pare
d to
IT d
iam
orph
ine
Fent
anyl
/Suf
enta
nil
App
ropr
iate
for P
CEA
Mep
erid
ine
= P
ethi
dine
Less
mat
erna
l nau
sea
and
sim
ilar p
atie
nt s
atis
fact
ion
com
pare
d to
IT
mor
phin
eLo
w ri
sk o
f dru
g ex
posu
re in
bre
astfe
d in
fant
s
App
ropr
iate
for P
CEA
Exte
nded
rel
ease
epi
dura
l mor
phin
ePr
olon
ged
post
oper
ativ
e an
alge
sia
Hig
h co
st-p
rice
Incr
ease
d pa
tient
mob
ility
and
dec
reas
ed s
taff
wor
kloa
dPo
ssib
le in
tera
ctio
n w
ith lo
cal a
nest
hetic
sC
loni
dine
(adj
unct
)Pr
olon
ged
post
oper
ativ
e an
alge
sia
Post
oper
ativ
e an
tihyp
eral
gesi
c pr
oper
ties
Dex
med
etom
idin
e (a
djun
ct)
Enco
urag
ing
resu
lts in
low
er a
bdom
inal
sur
gery
No
stud
ies
in c
onte
xt o
f ces
area
n de
liver
yN
eost
igm
ine
(adj
unct
)R
educ
es p
osto
pera
tive
mor
phin
e re
quire
men
tsM
ore
rese
arch
requ
ired
Mag
nesi
um (a
djun
ct)
Red
uces
pos
tope
rativ
e m
orph
ine
requ
irem
ents
Mor
e re
sear
ch re
quire
dSY
STEM
ICIN
TRAV
ENO
US
Mor
phin
eA
ppro
pria
te fo
r IV
PCA
Prur
itus,
PON
V, r
espi
rato
ry d
epre
ssio
nFe
ntan
ylA
ppro
pria
te fo
r IV
PCA
Mep
erid
ine
= P
ethi
dine
Neo
nata
l neu
robe
havi
oral
dep
ress
ion
Alfe
ntan
ilFa
st o
nset
of a
ctio
nH
igh
cost
-pric
eIn
tere
stin
g in
com
bina
tion
with
mor
phin
eIN
TRA
MU
SCU
LAR
and
Ease
of a
dmin
istra
tion
Inje
ctio
n is
unc
omfo
rtabl
e fo
r pat
ient
sSU
BCU
TAN
EOU
SLo
w c
ost-p
rice
Var
iabl
e bl
ood
leve
ls a
nd in
terv
al re
quire
d fo
r abs
orpt
ion
Long
his
tory
of u
se in
pos
tpar
tum
wom
enH
igh
staf
f wor
kloa
dPo
orly
repo
rted
in li
tera
ture
OR
AL
Oxy
codo
neC
ase
repo
rts o
f neo
nata
l res
pira
tory
dep
ress
ion
Mor
phin
ePo
orly
repo
rted
in li
tera
ture
Prur
itus,
PON
V, r
espi
rato
ry d
epre
ssio
nTr
amad
olC
ompa
tible
with
bre
astfe
edin
gPO
NV
LOC
AL
AN
ESTH
ETIC
TEC
HN
IQU
ES T
AR
GET
ING
PER
IPH
ERA
L N
ERV
EA
FFER
ENTS
ILIO
ING
UIN
AL
AN
D IL
IO-
HY
POG
AST
RIC
(III
H)
NER
VE
BLO
CK
WO
UN
D IN
FILT
RAT
ION
Goo
d po
stop
erat
ive
anal
gesi
aA
ppro
pria
te fo
r con
tinuo
us te
chni
que
Prol
onge
d po
stop
erat
ive
anal
gesi
a
Rel
ativ
ely
shor
t dur
atio
n of
act
ion
Mor
e re
sear
ch to
eva
luat
e co
ntin
uous
tech
niqu
eis
requ
ired
Con
flict
ing
resu
lts in
lite
ratu
reR
elat
ivel
y hi
gh c
ost o
f dis
posa
ble
devi
ces
TAP
BLO
CK
Prol
onge
d po
stop
erat
ive
anal
gesi
a (u
p to
2 d
ays)
Diff
icul
t in
obes
e pa
tient
sEa
sy to
per
form
Ris
k of
per
itone
al p
unct
ure
(sol
utio
n: u
ltras
ound
)Fe
w c
ompl
icat
ions
SYST
EMIC
AD
MIN
IS-
TRA
TIO
N O
F N
ON
- OPI
OID
A
NA
LGES
ICS
Para
ceta
mol
Non
ster
oida
l ant
iinfla
mm
ator
y dr
ugs
Littl
e ris
k as
soci
ated
with
par
acet
amol
ther
apy
Com
patib
le w
ith b
reas
tfeed
ing
Targ
ets
also
the
visc
eral
com
pone
nt o
f pos
t-ces
area
n se
ctio
n pa
inPo
tent
ial p
robl
ems
with
ble
edin
g, p
late
let d
ysfu
nctio
n an
d re
nal i
nsuf
ficie
ncy
Wel
l-doc
umen
ted
opio
id-s
parin
g ef
fect
sR
isk
of u
terin
e at
ony
in p
ostp
artu
m p
erio
dC
ompa
tible
with
bre
astfe
edin
gC
OX2
-inhi
bito
rsD
ecre
ase
NSA
ID-r
elat
ed a
dver
se e
ffec
ts (o
n pl
atel
et a
nd g
astro
-inte
stin
al
syst
ems)
Poor
ly re
porte
d in
lite
ratu
re
Ket
amin
eA
nti-h
yper
alge
sic
prop
ertie
sC
onfli
ctin
g re
sults
in li
tera
ture
No
data
on
trans
fer i
n br
east
milk
Gab
apen
tinM
ore
rese
arch
requ
ired
Tabl
e I.i
ndd
118
/02/
13
16:0
5
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150 s. Verstraete and M. Van de Velde
experience vomiting postoperatively. All of them would not have experienced these side effects with-out treatment (19).
Morphine delivered via neuraxial (both intra-thecal and epidural) routes increases the risk of herpes labialis (oral herpes) reactivation (27). Con-sequently, a primary concern from this side effect is the risk of maternal transmission to the neonate. However, withholding the benefits of these cost- effective analgesic techniques outweigh the risk of the small possibility of transmitting herpes simplex virus (HSV) to the newborn (27).
Although rare, respiratory depression is a potentially serious risk after neuraxial opioid ad-ministration, with an estimated incidence ranging from 0% to 0.9% (28). After intrathecal morphine, respiratory depression is usually delayed, due to rostral spread in cerebrospinal fluid and slow pene-tration in the brainstem. This risk is not significantly increased with neuraxial compared with parenteral opioid administration (28).
To the best of our knowledge, few data exist about prenatal and postnatal exposure to morphine after a subarachnoid injection. Despite its long history of use, only one case report illustrates the safety of intrathecal morphine in lactating mothers (29).
Intrathecal diamorphine
Diamorphine, which is commonly used in the United Kingdom to provide analgesia after sur-gery (30), has several desirable properties for use as an analgesic through an intrathecal route. Due to its high lipophilicity, it has a quicker onset of action as compared with morphine. Although diamorphine has a short half-life into the cerebrospinal fluid, it diffuses into neural tissues, and is de-acetylated into its active metabolites 6-mono-acetylmorphine and morphine. Those events increase its duration of ac-tion (31). Intrathecal diamorphine has been shown to be as effective as morphine for post-cesarean an-algesia (32). Moreover, when administered intra-thecally, diamorphine 250 µg has been found to be as effective as fentanyl 15 µg during surgery for cesarean delivery (33). Consequently, diamorphine is an attractive opioid in providing both intra- and prolonged postoperative analgesia. Several studies have indicated that the optimum dose of diamor-phine is between 250 and 375 µg, with more side effects at the higher end of the dose range, among which itching and vomiting are particularly fre-quent (31, 33).
but is clinically irrelevant in terms of both maternal side effects and effects on the breastfeeding infant, as the doses typically used in the spinal space are small (24). This finding is of great importance, par-ticularly for breast-feeding women and is an advan-tage of neuraxial modes of post-cesarean analgesia as compared with the larger doses of opioids re-quired systemically.
The use of intrathecal morphine, diamorphine, fentanyl, sufentanil, meperidine, nalbuphine and buprenorphine for post-cesarean pain management is described hereafter.
Intrathecal morphine
Intrathecal morphine, as part of a multimodal analgesic regimen, is a common and effective strat-egy for providing post-cesarean delivery analgesia and is often seen as the “gold standard” treatment. Indeed, it meets the criteria of ease of administra-tion, good side effect profile, minimal to no effects on fetus through breastfeeding and highly effective at controlling pain (25, 26). palMer et al. random-ized 108 parturient women undergoing cesarean de-livery at term to receive a single dose of intrathecal morphine (from 0 to 500 µg) (25). Morphine con-sumption through a patient-controlled analgesia (PCA) device appeared to be fairly stable in patients receiving a dose between 75 and 500 µg, suggesting a ceiling analgesic effect with doses above 75 µg. Despite a more than fivefold increase in the dose of intrathecal morphine, analgesia remained largely unchanged. However, pruritus severity was found be directly linked to intrathecal morphine dosage. In contrast, other common opioid-related side effects, such as nausea and vomiting, were not found to have any dose-dependent relationship. In conclu-sion, the data of this study indicate that there is little justification for the use of more than 0.1 mg of mor-phine intrathecally for post-cesarean analgesia.
Both intrathecal and epidural morphine share a similar side effect profile. The five classic side ef-fects are pruritus, nausea and vomiting, urinary re-tention, oral herpes reactivation and respiratory de-pression (22). A meta-analysis revealed that the number of patients needed to be treated with 50 to 250 µg of intrathecal morphine to harm one indi-vidual (NNH) was 2.6 (95% CI, 2.1-3.3) for pruri-tus, 6.3 (95% CI : 4.2-12.5) for nausea, and 10.1 (95% CI : 5.7- 41.0) for vomiting, respectively (19). When administering the dose recommended by PalMer et al. (100 µg) to 100 parturient patients scheduled for cesarean section, 43 women will ex-perience pruritus, 10 will be nauseous and 12 will
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post-cesarean sectIon analgesIa 151
their use in an obstetric setting is currently not strong enough.
Epidural opioids
Epidural infusions of local anesthetic agents alone may be used for postoperative analgesia, but, in general, they are not as effective at controlling pain as local anesthetic-opioid combinations (45). The general mechanism of action of epidural opi-oids is somewhat the same as after intrathecal injec-tion, with, however, both spinal and supraspinal (via systemic delivery) sites of action (45). This complexity is due to the presence of a dural barrier, to epidural fat that act as a drug depot compartment, and to the increased vascularity of the epidural com-partment during pregnancy. The epidural space con-tains an extensive venous plexus. Therefore, the in-travascular reabsorption of opioids following epidural administration is extensive. Epidural ad-ministration of morphine, fentanyl, or sufentanil produces opioid blood concentrations that are simi-lar to an intramuscular injection of an equivalent dose (22).
Morphine’s low lipid solubility and prolonged duration of action often allows a single bolus dose offering satisfactory analgesia for the first 24 hours. More lipid-soluble opioids, such as fentanyl and sufentanil have a shorter duration of action, render-ing them better suited to patient- or nurse-controlled PCEA techniques in combination with low-dose local anesthetic agents.
A concern regarding epidural analgesia is a possible impact on breastfeeding. An Australian retrospective trial with 1280 women demonstrated an association, but not a causal link, between epi-dural usage and breastfeeding success (47). How-ever, at this moment, there is no prospective, ran-domized evidence that epidural analgesia causes reduced breastfeeding success (48). In contrast, in a randomized controlled trial, WIlson et al. found no effect of epidural fentanyl on breastfeeding initia-tion and duration (49).
Epidural morphine
palMer et al. conducted a dose-response study with epidurally administered morphine for post- cesarean pain management. Similarly to intrathecal administration, a ceiling effect became appar-ent (50). Their data indicate that the degree and du-ration of analgesia increase in a dose-related man-ner with the dose of epidural morphine from 0 to 3.75 mg. Even the smallest dose in this series,
Intrathecal fentanyl or sufentanil
Intrathecal fentanyl and sufentanil provide ex-cellent intraoperative analgesia (34, 35, 36) and are widely given for this purpose. Because of their rela-tively short duration of action, however, there is little postoperative analgesic benefit to a single dose added to the local anesthetic solution at the time of cesarean delivery. Moreover, they do not reduce opioid consumption during the first 24 postopera-tive hours (35). Given its higher µ-receptor affinity, initial analgesia (0-6 h post-cesarean section) may be slightly better with sufentanil (2.5 and 5 µg) than with fentanyl (10 µg) (35). The combination of one of these opioids with morphine offers no advantage over intrathecal morphine alone (34, 37).
The incidence of pruritus is very high, but sim-ilar, with spinal morphine, fentanyl and sufentanil. However, nausea and vomiting occur less frequent-ly as compared with morphine (19). Finally, the risk of delayed respiratory depression is relatively small with intrathecal fentanyl and sufentanil, due to their segmental effect and lack of rostral spread in the cerebrospinal fluid (28).
Intrathecal meperidine (= pethidine)
Meperidine is an opioid of intermediate lipid solubility and is unique in having significant local anesthetic properties, which can lead to undesirable motor blockade in patients desiring active ambula-tion during the postoperative period (38). It can be used as the sole spinal drug for cesarean delivery, particularly in those with contraindication to local anesthetic agents (39, 40). In a randomized, double-blind controlled trial, the addition of meperidine 10 mg to intrathecal bupivacaine prolonged post-cesarean analgesia compared with placebo (38). However, the duration of effective analgesia was limited to approximately 4 h, and the overall cumu-lative morphine consumption at 24 h was similar in both the meperidine group and the control group. Moreover, spinal meperidine 10 mg was found to be associated with more nausea and vomiting than fentanyl and sufentanil (41), which has further limited its popularity.
Intrathecal nalbuphine or buprenorphine
Nalbuphine 0.8 mg (42) and buprenorphine 50 and 150 µg (43, 44) have been administered neur-axially for post-cesarean analgesia, although more rarely than other opioids. Despite a more favorable side effect profile than intrathecal morphine, wom-en generally experience less pain control with those medications. Consequently, the evidence to support
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Epidural diamorphine
In the United Kingdom, epidural diamorphine is, similarly to intrathecal diamorphine, very popu-lar for post-cesarean section pain management. In-deed, it provides excellent and prolonged postoper-ative analgesia (52). A British audit showed that a single dose of 2-3 mg epidural diamorphine during elective cesarean section offered mild or low less pain scores to over than 92% of parturient patients. Nausea was found to be uncommon. Contrarily, the incidence of pruritus was high, but this was not troublesome for most women (52). When compared with 0.3 mg spinal diamorphine, 3 mg epidural dia-morphine provides similar duration and quality of analgesia. Pruritus is more common and more se-vere after subarachnoid diamorphine (53). caranza et al. compared two boluses of epidural diamor-phine 3 mg with a single 200 µg spinal dose of mor-phine and found no significant differences in pain scores, incidence of itching, sedation or respiratory depression (54). However, time to first request for rescue analgesic drugs was longer (mean ± SD : 22.3 ± 12.0 h versus 13.8 ± 6.5 h, p = 0.04) and in-cidence of PONV was higher (73% versus 41%, p = 0.01) in the intrathecal morphine group than in the epidural diamorphine group.
Epidural meperidine (= pethidine)
Patient-controlled epidural analgesia with me-peridine has been shown to produce high-quality
1.25 mg, had a modest PCA morphine-sparing ef-fect that persisted throughout the 24-hour study pe-riod. However, analgesia (as measured by PCA morphine use) was not enhanced when increasing the dose above 3.75 mg up to 5 mg (Fig. 1). Further-more, parturients continued to use the intravenous morphine PCA at a relatively constant rate, even in the large-dose groups. The latter finding lends fur-ther support to the theory of the importance of both spinal and supraspinal opioid receptor occupation.
The general side effect profile of epidural morphine is somewhat the same as with intrathecal morphine. Pruritus and post-operative nausea and vomiting (PONV), however, tend to be less related to dose when administered epidurally (50).
In the last decade, no randomized controlled studies compared the use of intrathecal and epidural morphine for elective cesarean delivery. In 2002, sarVela et al. randomized 150 parturients sched-uled for elective cesarean section into a double-blinded trial to receive intrathecal morphine 0.1 mg (IT 0.1 group) or 0.2 mg (IT 0.2 group) or epidural morphine 3 mg (epidural group) (51). All patients additionally received ketoprofen 300 mg/d. Pain control was equally good in all three groups with an overall high maternal satisfaction. Although mothers in the IT 0.1 group requested rescue analgesics more often than in the other groups, the authors concluded that spinal morphine 0.1 mg is superior for post-cesarean analgesia, because of a decreased incidence of itching (Fig. 2).
Fig. 1. — Total 24-h patient – controlled analgesia (PCA) morphine use. Data are mean (± 95% confidence interval). Groups were significantly different (analysis of variance, p < 0.001) ; *Group 0.0 mg was significantly different from Groups 2.5, 3.75, and 5.0 mg ; **Group 1.25 was significantly different from Groups 3.35 and 5.0 mg (a posteriori, p < 0.05).Adapted from : Palmer N. J., et al., anest. analg., 90, 887-891, 2000.
Fig. 2. — Percentage of patients with itching and PONV and those requesting treatment with epidural (3 mg) and intrathecal (100 and 200 p.g) morphine. Patients in the 100 µg IT mor-phine group had less itching, required less interventions for itching but required more rescue analgesia.Adapted from : Sarvela J., et al., anest. analg., 95, 436-440, 2002.
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cesarean delivery, leads to more effective pain relief when compared to ropivacaine 0.2% alone, particu-larly during the early postoperative period (65). In summary, although the clinical benefit is uncertain, most support the analgesic benefit of adding local anesthetic agents to the solution, but this runs the risk of motor blockade.
Choosing between fentanyl and sufentanil
In a large double-blind trial, including 250 par-turient patients scheduled for an elective cesarean section, the investigators randomized patients into two PCEA groups : group F (n = 125) received fentanyl 2 µg/ml with bupivacaine 0.01% and epinephrine 0.5 µg/ml and group S (n = 125) re-ceived sufentanil 0.8 µg/ml with bupivacaine 0.01% and epinephrine 0.5 µg/ml. The initial infusion rate was 16 ml/h with on-demand boluses of 3 ml every 15 min (66). Overall maternal satisfaction, pain-scores and side effects during PCEA were not sig-nificantly different between groups. Total number of PCA requests was greater for group F than for group S (106.7 ± 312 vs. 70.8 ± 138, P < 0.05). A couple of hours after discontinuation of the PCA, 1 patient in group F and 42 patients who received sufentanil complained of lightheadedness and dizziness (P < 0.0001). Consequently, the authors concluded that epidural sufentanil offers no benefits over fentanyl administered by the same route.
Extended release epidural morphine
In the setting of cesarean section, the primary limitation of epidural analgesia with a single shot of standard morphine is its short duration of action, which is typically less than 24 h. The use of con-tinuous epidural catheter techniques prolongs anal-gesia but reduces patient mobility and increases the staff workload. Consequently, a long-acting, slow-release opioid such as extended release epidural morphine (EREM) may theoretically be a better an-algesic option after cesarean section. Indeed, pain is often more intense on the second post-cesarean sec-tion day, when a single shot neuraxial morphine is no longer effective. EREM (DepoDur®) delivers conventional morphine via a multi-vesicular lipid, sustained-release drug-delivery technology (Depo-Foam®), resulting in prolonged drug delivery (67) (Fig. 3). In a multi-center, randomized, controlled trial, the investigators compared a single epidural injection of either 5 mg of standard morphine and 5, 10 or 15 mg of EREM for post-cesarean section pain control (67). A Single EREM dose of 10 and 15 mg resulted in a significant decrease in total
pain relief in post-cesarean section patients (55, 56, 57, 58). Various regimens have been validated. Usually, it consists of a loading dose (50 mg given epidurally at the end of the operation), followed by 20 to 25 mg boluses with a lock-out interval ranging from 10 to 20 minutes (55, 56, 59). The addition of a continuous background infusion is of no bene-fit (60). Administration through the epidural route (meperidine PCEA) significantly lowers pain scores, both at rest and during coughing. It increases maternal satisfaction when compared with a meper-idine intravenous PCA (57). Subarachnoid mor-phine 0.2 mg provides superior pain relief than epi-dural meperidine during the first 12 h, but is associated with more severe maternal nausea and pruritus. Moreover, spinal morphine and meperi-dine PCEA provides similar patient satisfac-tion (58). A recent observational study showed that breastfed infants are at low risk of drug exposure when mothers self-administer epidural meperidine after cesarean section (59).
Epidural fentanyl and sufentanil
In so far as fentanyl and sufentanil are lipid soluble, and therefore have a relatively short dura-tion of action, they are better suited to be adminis-tered through a patient-controlled epidural tech-nique. The relative analgesic potency of epidural sufentanil as compared with fentanyl is approxi-mately 5. No major differences between these two opioids are found regarding onset, duration and ef-ficacy of post-cesarean section analgesia, when equipotent analgesic epidural doses are adminis-tered postoperatively (61).
Early studies have revealed that epidural fen-tanyl infusions produce similar levels of post-cesar-ean section analgesia with an equal side effect pro-file at 12 and 24 h as compared with the intravenous route (62). When compared with epidural pethidine, no difference exist in terms of pain level outcomes, but epidural fentanyl results in more opioid-related side effects and lower maternal satisfaction (63). The clinical benefit of adding a local anesthetic to fentanyl remains uncertain. Although one study re-vealed a 57% reduction in fentanyl consumption, overall maternal satisfaction was not modified (64). In contrast, another trial showed that the addition of small amounts of local anesthetic agents (0.01% bu-pivacaine) or epinephrine not only reduces total fen-tanyl consumption, but also improves patient satis-faction and adverse effect profile (21).
Similary, the combination of sufentanil 0.75 µg/ml with ropivacaine 0.2% for PCEA after
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epidural (PCEA) routes. When activating the delivery system, hospital staff members place limits on the number of doses of analgesic medication per unit of time that will be administered to the patient. There is also a minimum time interval (lockout interval) that must elapse between two administra-tions. A continuous background infusion super-imposed on patient-controlled boluses can also be implemented, as discussed later on.
Patient controlled techniques have several advantages, including the lack of waiting time for patients before a caregiver can increase the dosage of medication. As a consequence, the patient spends less time in pain, blood drug concentrations are more stable and patients tend to use less medication than in cases in which medication is given accord-ing to a pre-determined schedule. Furthermore, PCA reduces staff workload and enhances women satisfaction, due to increased autonomy and feeling of control (69).
The disadvantages of using PC(E)A in post-cesarean section women include a lack of mobility if local anesthetic agents are used, and the fact that those devices are often quite cumbersome. This can potentially interfere with maternal care of the new-born (4). Other drawbacks are related to financial considerations (70), and the necessity for an avail-able skilled professional to troubleshoot eventual inadequate analgesia, device malfunctions and pro-gramming errors (71, 72).
The question of administering a background continuous infusion of opioids in addition to PCEA demand mode or not is controversial. In the post-cesarean section settings, patients may not use the
supplemental opioid consumption (Fig. 4) and VAS-scores (both at rest and with activity) at 24 and 48 h. It is unclear whether this effect is due to the higher morphine dose or the extended release formulation. This prolonged effect into the period of full patient activity is very attractive. Nevertheless, caution must be applied when EREM is administered to women who have had epidural analgesia using a lo-cal anesthetic agent, since epidural lidocaine has been shown to alter the pharmacokinetics and drug effects of EREM (68). More research is required to elucidate the mechanisms and implications of this interaction. A major limitation to a more widespread use of EREM is its high cost, which is difficult to justify when cheaper alternatives are available to provide adequate pain relief after the first 24 h (4).
Patient-controlled (epidural) analgesia [PC(E)A]
Patient-controlled analgesia (PCA) is any method of allowing a person in pain to administer their own pain relief medications. PCA can be delivered through oral, intravenous, subcutaneous, intrathecal and, for this chapter most importantly,
Fig. 3. — Illustration of DepoFoam particles. The nonconcen-tric versicles are surrounded by a lipid membrane and each contains an internal aqueous chamber with encapsulated morphine sulfate solution.Image courtesy of Pacira Pharmaceuticals Inc., with permis-sion.
Fig. 4. — Use of supplemental opioid analgesics (in morphine milligram equivalents) during the 48 h after the study dose. *P = 0.0134) ; +P = 0.0108 ; §P = 0.0065.Adapted from : Carvalho B., et al., anest. analg., 100, 1150-1158, 2005.
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morphine requirements, an effect that lasted ap-proximately 10 hours (81). Over the dose range studied (10-100 µg), intrathecal neostigmine pro-duced reductions in morphine use, independently from the administered dose, but a trend towards a dose-dependent increase in the occurrence of nau-sea and vomiting. This clinical trial suggested that doses lower than or equal to 10 µg may be adequate as an analgesic adjunct, without increasing the risks of nausea. Nonetheless, aforementioned adverse effects have dispirited further research to use neo-stigmine by this route. In contrast, the risk of post-operative nausea and vomiting appears to be low and independent form the dose when using epidural neostigmine. Administration of 75 to 300 µg epidurally resulted in a global reduction in pain in-tensity during the first 24 hours from 5.4 ± 0.2 in the saline group to 3.0-3.5 ± 0.3 in the neostigmine groups. This effect was also independent from the administered dose (82). Although these data are en-couraging, more studies in obstetric patients are re-quired to validate utility and promote routine use of epidural neostigmine.
Magnesium has anti-nociceptive properties, due to its non-competitive N-methyl-D-aspartate receptor antagonism. It blocks its ion channel in a voltage-dependent manner (83). Intrathecal admin-istration of magnesium sulfate (MgSO4) signifi-cantly potentiates opioid antinociception (84, 85). Magnesium sulfate (MgSO4) alone, however, in addition to spinal local anesthetic agents, does not shorten the onset time of sensory and motor block-ade, nor prolongs the duration of spinal anesthe-sia (86). Similarly, addition of 500 mg of magne-sium and 1.5 mg of morphine to 10 mL of epidural 0.1% bupivacaine reduces postoperative pain as compared with the addition of morphine or magne-sium alone, or with an additive-free solution (87). Up to now, there is limited information about the safety of neuraxial magnesium in humans. How-ever, Goodman reported that accidental administra-tion of 9 g of magnesium through an epidural catheter did not induce any signs or symptoms of focal neurological toxicity (88). A meta-analysis by lysakoWskI et al. showed that supplemental magnesium can provide perioperative analgesia without side effects (89).
systeMIc adMInIstratIon of opIoIds
Systemic opioids are used for post-cesarean section pain management on a regular basis, partic-ularly after general anesthesia (12). Opioids can be
demand mode for various reasons, such as fear for addiction. This may result in inefficient pain con-trol, unless a basal infusion is used. However, this background infusion may decrease the safety of PCEA. Continuing drug administration even if the patient is pain free or sedated may be danger-ous (23). Wong et al. (73) and Vercauteren et al. (74) do not recommend the addition of a back-ground infusion as they did not find any additional benefits over the demand-only mode. Moreover, pa-tients in their background infusion group had a higher total drug consumption, and a higher inci-dence of adverse effects. In contrast, in their ran-domized, double-blind study after gastrectomy, KoMatsu et al. report lower VAS-scores without more serious side effects in the background infusion group as compared with the demand-only PCEA group (75).
Neuraxial adjuncts
In attempts to improve the quality of intra-operative anesthesia and postoperative analgesia, several non-opioid agents have been employed in conjunction with subarachnoid and epidural opioids and/or local anesthetic agents. In particular, the ad-dition of clonidine, an α2-adrenoreceptor agonist, has been widely studied. The addition of clonidine (up to 150 µg) alone to spinal bupivacaine for post-cesarean section analgesia does not appear to be sufficient (76). In contrast, the combination of sub-arachnoid morphine 100 µg and at least 60 µg of clonidine was found to increase the duration of post-cesarean section analgesia and reduce the need for supplemental analgesic agents. It also mildly in-creased intraoperative (but not postoperative) seda-tion (76). In a randomized controlled trial conduct-ed by capogna et al., adding clonidine 75 or 150 µg to a modest dose of epidural morphine 2 mg pro-longed the duration of post-cesarean section analge-sia from 6.27 hours (control group) to 13.25 and 21.55 hours, respectively (77). Beyond its analgesic properties, clonidine also possesses postoperative antihyperalgesic qualities (78).
Dexmedetomidine is a new highly selective α2-agonist, which has recently been under evalua-tion as a neuraxial adjuvant. Up to now, its use in the context of cesarean delivery has not yet been investigated. However, the addition of dexmedeto-midine 5 µg intrathecally or 1.5 µg/kg epidurally in the setting of lower abdominal surgery seem to be encouraging (79, 80).
In a study of krukoWskI et al., intrathecal neo-stigmine was associated with reduced postoperative
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appears to be rapidly metabolized, redistributed, or both, and has not been shown to cause adverse neo-natal effects (99).
The question of administering a background continuous infusion of opioids in addition to those delivered on demand through the IV-PCA device is as controversial as during PCEA administration. In a recent double-blind study, 60 ASA 1 or 2 patients scheduled for abdominal hysterectomy were ran-domly allocated to a group receiving a background continuous morphine infusion of 0.5 mg/h (100) in addition to IV-PCA morphine, or to a group not receiving the additional continuous infusion. The continuous basal infusion was not found to lower pain scores during movement or at rest, but induced higher pain intensity, higher opioid usage and more complications such as nausea, vomiting and dizziness. The most likely explanation for these re-sults is the possible development of acute tolerance to the postoperative continuous infusion of mor-phine and/or opioid-induced hyperalgesia (100). In contrast, a study of WhIte et al. showed opposite findings (101). According to this trial, adding a 0.01 mg/kg/h background infusion of morphine to an on demand scheme results in 25% reduction of total morphine consumption over the first 48 post-operative hours (Fig. 6). It also favors lower pain scores and greater patient satisfaction on a 10-scale numerical rating scale. Noteworthy, although not specifically documented in cesarean section pa-tients, background IV-PCA infusions of opioids in postsurgical patients increase the risk of respiratory depression (102).
administered by nurses on patient’s request or through a PCA device.
Intravenous opioids
Patient-controlled intravenous opioids are popular after cesarean section, because of low fluc-tuation in plasma opioid concentration and consis-tently high maternal satisfaction. General advan-tages and disadvantages are the same as with opioids administered through a PCEA device (see above). When compared with neuraxial opioids, intrave-nous PCA (IV-PCA) is constantly associated with a lower quality of analgesia (90, 91). In terms of pa-tient satisfaction, literature findings are inconsis-tent. Some studies (92, 93) demonstrated higher sat-isfaction scores with IV-PCA than with neuraxial opioids. This is probably due to the increased au-tonomy that comes with a IV-PCA technique. The higher incidence of pruritus with epidural opioids as compared with IV-PCA (Fig. 5) may also have re-sulted in less maternal satisfaction with the former. In contrast, egan et al. and rapp-zIngraff et al. found better satisfaction with epidural morphine, as compared with IV-PCA morphine (91, 94).
Morphine and fentanyl are both appropriate opioids for use through an IV-PCA in obstetrics (4), in contrast to meperidine. WIttels et al. revealed that among nursing parturients after cesarean sec-tion, IV-PCA meperidine (= pethidine) was associ-ated with more neonatal neurobehavioral depres-sion than IV-PCA morphine. In this study, nursing infants exposed to morphine remained more alert and oriented to animate human auditory cues than those exposed to meperidine (95). Compared to morphine, alfentanil has a much faster onset of ac-tion because of its higher lipid solubility and high un-ionised fraction (89%) in the plasma at physio-logical pH (96). Consequently, the combination of those two may be advantageous in relation to the speed of onset (97). Although the addition of alfen-tanil to morphine was found to be beneficial, it adds also significantly to the cost per patient (97). The addition of remifentanil to long-acting intravenous patient-controlled opioids has been investigated after major abdominal surgery, but not yet after cesarean delivery (98). Adding remifentanil to an IV-PCA tramadol administration resulted in better pain scores, lower analgesic agent consumption, and fewer side effects, when compared with trama-dol alone. However, the remifentanil analgesic out-come in the morphine-remifentanil group was not as prominent as in the tramadol-remifentanil group (98). Remifentanil crosses the placenta, but
Fig. 5. — Percentage of patients in each group reporting no, mild or intense pruritus and nausea. *P < 0.05.Adapted from : Rapp-Zingraff N., et al., Int. J. obstet. anest., 6, 87-92, 1997.
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possibly fewer opioid-related adverse effects as compared with the intravenous or neuraxial route, and avoidance of IV-PCA device-associated com-plications (103, 104, 105, 106). Some physicians have concerns about administering an oral medica-tion immediately after an abdominal surgery. They are concerned about the reduced gastrointestinal motility, decreased absorption of the medication, and increased incidence of nausea and vomiting. However, cesarean section is usually performed un-der regional anesthesia. This type of surgery in-volves minimal, if any, manipulation of the bowel. Additionally, studies have demonstrated that the early initiation of solid food is well-tolerated after cesarean delivery (107). To enhance patient satis-faction, oral analgesia should be provided at fixed time intervals with additional “on-demand” dosing, rather than leaving it to patient request (103).
Oxycodone, a semi-synthetic opioid derived from thebaine, has been gaining popularity post-cesarean section analgesia (104, 106). In 2005, daVIs et al. compared IV-PCA morphine with a fixed dose combination of oxycodone and paracetamol (5 mg/325 mg tablets, two tablets 3-4-hourly, maximum 12 tablets during the first 24 h) (104). The regimen included intravenous ke-torolac 30 mg and unrelieved pain was treated using intramuscular pethidine. Lower pain scores were found at the 6th and 24th postoperative hour in the oral analgesia group (VAS 3.2 ± 1.8 versus 4.1 ± 2.5, p = 0.04 and 2.9 ± 1.7 versus 4.1 ± 2.1, p = 0.004 respectively). In the same group, nausea and drows-iness were also less common at the 6th hour, but nau-sea was slightly more frequent at 24th hour. In a ran-domized controlled trial, Mcdonnell et al. confirmed that a multimodal regimen consisting of regular oral non-opioids and oxycodone provides satisfactory analgesia after cesarean section, result-ing in early postoperative analgesia of a similar quality to a regimen based on intrathecal morphine (Fig. 7) (106). Surprisingly, despite a higher inci-dence of pruritus, the intrathecal morphine regimen was associated with higher maternal satisfaction scores than in the oxycodone-group. This may have probably been a consequence of factors such as less severe episodic pain and less frequent requirements for rescue analgesic medications. It suggests that post-cesarean mothers consider consistently good pain relief more important than side effects such as pruritus. Notwithstanding, despite the evidence of an accumulation of oxycodone in breast milk for up to 72 hours, seaton et al. state that the use of oral oxycodone (in doses ≤ 90 mg in a 24 h period) for analgesia after cesarean section poses only minimal
Intramuscular and subcutaneous opioids
The advantages of intramuscularly and subcu-taneously administered opioids are their ease of ad-ministration, low cost and long history of use in postpartum women. However, there are several se-rious limitations to their use. First, this mode of ad-ministration often requires repeated injections, and this may be uncomfortable for the patient. Second, intramuscular or subcutaneous administration provokes peaks and valleys of the opioid blood con-centration. Valleys can affect pain relief, while peaks increase the incidence of adverse effects. Ob-tained blood levels are also likely to vary consider-ably between individuals. In addition, after the in-jection, pain relief is not immediate. The time interval needed for the resorption of the drug from the site of injection, and for the drug to reach opioid receptors is variable. In an era of nursing staff short-ages, intramuscular and subcutaneous opioids may be inconvenient for the nursing personnel and the patient. Finally, these methods are rarely used in clinical trials and, consequently, poorly reported in the literature.
Oral opioids
Oral opioids are commonly employed as relay analgesic agents after a primary management using neuraxial or intravenous opioids. The potential ben-efits of using oral opioids as the primary post-cesar-ean section analgesic method include the ease of administration, low cost, high maternal acceptance,
Fig. 6. — Total morphine consumption (mean ± SD).a : P = 0.034) ; b : P < 0.0001).Adapted from : White I., et al., pharMacol. res., 66, 185-191, 2012.
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pain control in women after caesarean section. The diclofenac/tramadol combination is associated with a higher incidence of nausea (113). The results of a recent investigation on the transfer of tramadol and its O-desmethyl metabolite into transitional breast milk, and the assessment of unwanted effects in the breastfed infants were reassuring (115). Short-term maternal use of tramadol during establishment of lactation is compatible with breastfeeding.
systeMIc adMInIstratIon of non-opIoId analgesIc agents
Paracetamol
The analgesic properties of paracetamol (= ac-etaminophen) have been attributed to the inhibition of the cyclo-oxygenase type 3 (COX-3) enzyme within the brain, a reduction in central nervous sys-tem prostaglandin E2 production and activation of descending serotonergic pathways (116).
When compared with placebo, paracetamol (or its injectable prodrug propacetamol) significantly reduces morphine consumption after major surgery (117). Several earlier studies and a recent meta-analysis have concluded that a paracetamol-non-steroidal anti-inflammatory drug (NSAID) combination works better than paracetamol alone, and, to a lesser extent, than NSAIDs alone (118). In this systematic review, twenty-one (n = 21) studies enrolling 1909 patients were analyzed. The NSAIDs used were ibuprofen (n = 6), diclofenac (n = 8), ketoprofen (n = 3), ketorolac (n = 1), aspirin (n = 1), tenoxicam (n = 1), and rofecoxib (n = 1). The com-bination of paracetamol and NSAID was found to be more effective in reducing postoperative pain and/or suplementary analgesia than paracetamol or NSAID alone in 85% and 64% of relevant studies, respectively. Of these 21 studies, two are particu-larly noticeable, because they were conducted in patients beneficiating from a cesarean section, and because diclofenac was the used NSAID in addition to IV or rectal propacetamol (119), followed by oral paracetamol (120). Both studies found that the com-bination significantly reduced supplementary anal-gesic consumption, as compared with paracetamol alone, but did not compare with diclofenac alone. Overall, there is little risk associated with paracetamol therapy (111, 117). Hence, it has been suggested as a “near-routine” medication for use within a multimodal post-cesarean section pain management plan. In a recently published article, Kulo et al. showed that peak and trough paracetamol
risks to the neonate. The incurred risk do not out-weigh the benefits of providing effective analgesia, maternal comfort and successful initiation of lacta-tion (108). However, case reports of serious neona-tal respiratory depression following oral opioids in lactating mothers have been described.
Data on the use of oral morphine after cesarean delivery are currently limited. Primary analgesia based on an oral morphine regimen has been evalu-ated in an open non-randomized study by JakobI et al. This study suggests that pain relief by oral mor-phine is satisfactory (105). Several local audit data also suggest a good patient acceptability of this medication (109, 110). Treatment of the mother with single doses of morphine is not expected to cause any risk for the suckling infant (111). Al-though these reports seem encouraging, oral mor-phine is yet to be the subject of a formal randomized controlled trial.
Tramadol is another alternative parenteral or oral analgesic agent for post-cesarean section pain (112, 113). It is a weak μ-opioid receptor ago-nist, it induces a serotonin release, and it inhibits the reuptake of norepinephrine. When metabolized, tramadol is converted to O-desmethyltramadol, a significantly more potent μ-opioid agonist (114). MItra et al. found that a combination of diclofenac and tramadol is significantly better than a diclofe-nac–paracetamol combination regarding overall
Fig. 7. — Area under the curve for scores of rest pain, move-ment pain and sedation in the first 24 h. No significant differ-ences between groups. Group O : Oral oxycodone ; group I : intrathecal morphine.Adapted from : McDonnell N. J., et al., Int. J. obstet. anaesth., 19, 16-23, 2010.
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surgery (117). However, data related to the obstetric setting are quite limited. fong et al. (132) found that perioperative celecoxib administration (400 mg) improves post-cesarean section analgesia dur-ing the first 24 h. Wong et al. (133) studied the ef-ficacy of post-cesarean section parecoxib. They al-located 66 parturient patients to two groups : the first group (n = 33) received an initial postoperative 40 mg intravenous bolus of parecoxib as a loading dose, followed by two boluses of 20 mg subse-quently given at intervals of 24 h. The other group received a ketorolac-based regimen (postoperative intravenous loading bolus of 30 mg followed by 90 mg of ketorolac combined with morphine into an IV-PCA device). No significant differences in terms of sedative side effects, mood state, quality of sleep and satisfaction were found between the two groups, but there was a lower total morphine requirement (22% reduction) in the parecoxib group (43.5 ± 19.2 versus 55.5 ± 21.5 in the ketorolac and parecoxib group, respectively, p = 0.02). Regarding adverse effects, there were no statistical differences between groups.
Ketamine
Due to the central role played by NMDA re-ceptors in central sensitization, NMDA-antagonists, such as ketamine, may be useful for their analgesic and anti-hyperalgesic properties (134). However, available data regarding the efficacy of ketamine against post-cesarean section pain are conflicting. Compared to placebo, suppa et al. (135) found a significantly reduced morphine consumption 4, 8, 12 and 24 h after cesarean section under subarach-noid anesthesia (total 31%) in the group receiving 0.5 mg/kg intramuscular S-ketamine 10 minutes af-ter birth, followed by a 2 µg/kg/min intravenous continuous infusion for 12 h. Several minor side ef-fects (drowsiness, diplopia, positive dysphoria and nystagmus) were observed in the ketamine group, but they were all short-lived and resolved within a few hours. In contrast to the aforementioned study, BIlgen et al. found no difference in morphine con-sumption or pain scores among groups treated with three different doses of intravenous ketamine (0, 0.25, 0.5, and 1 mg/kg) prior to general anesthe-sia (136). bauchat et al. didn’t find an additional postoperative analgesic benefit of low-dose ket-amine (10 mg) either in patients who received intra-thecal morphine and intravenous ketorolac (137). The addition of ketamine intrathecally has also re-vealed disappointing (138). No detrimental effect on uterine blood flow or fetal hemodynamics has
concentrations in women following cesarean deliv-ery were lower than in non-pregnant patients. This is due to a higher clearance and a larger distribution volume. Consequently, in the future, reducing the interval between consecutive doses (typically every 6 hours, at present) or increasing the regular dose (typically 1 g, at present) may be considered during the postpartum period. It emphasizes the need for integrated pharmacokinetic and pharmacodynamic studies related to peripartum analgesia (121).
Non-steroidal anti-inflammatory drugs (NSAIDs)
As mentioned above, pain after a cesarean sec-tion may have at least 2 components : somatic pain originating from the surgical wound itself, and vis-ceral pain arising from the uterine incision and in-volution. Although somatic pain may be relieved by opioids, the treatment of visceral pain may reveal more difficult. As NSAIDs are very effective for re-lieving pain related to menstrual cramping, interest has grown in the use of NSAIDs to treat the visceral component of post-cesarean section pain. Several different NSAIDs and administration routes have been investigated, including ketorolac (122, 123), intramuscular (124) and rectal (125) diclofenac, oral naproxen (126), dipyrone (105), ibupro-fen (103) and others. Overall, the addition of NSAIDs to a post-cesarean section analgesic regi-men has been very successful, both at improving the quality of analgesia resulting from neuraxial or sys-temic opioids, and at reducing opioid-related side effects (117, 124). Despite these well-documented opioid-sparing effects and the compatibility with breastfeeding (111), NSAIDs must be used with caution. They carry the risk of bleeding, platelet dysfunction and renal insufficiency. Concern has also been raised with regard to uterine atony during the postpartum period (127). Cases of severe uter-ine atony associated with a ketorolac (128) or di-clofenac (129) administration have been reported. Consequently, the use of NSAIDs in women at risk of postpartum hemorrhage, or suffering from a pre-eclampsia-induced renal impairment deserves cau-tion.
The introduction of the cyclo-oxygenase 2 (COX2) specific inhibitors has the potential to de-crease adverse effects, particularly with regard to the platelet and gastro-intestinal systems. When ad-ministered in low doses, they are also very unlikely to cause untoward effects in breastfed infants (130, 131). Studies comparing COX2-inhibitors to NSAIDs, have demonstrated similar analgesic effi-cacy and opioid-sparing effects after non-obstetric
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siveness as compared with neuraxial blocks, their suitability for patients undergoing general anesthe-sia (146), and the possibility of repeating them post-operatively if required. Ultrasonography has been used to improve quality and safety of peripheral nerve blockade (147, 148). Instead of relying on fascia “clicks” and “pops”, ultrasound offers real-time guidance and precision in needle placement.
Ilioinguinal and iliohypogastric (IIIH) nerve blocks
The Pfannensteil incision lies within the L1 dermatome, which is supplied by the iliohypogas-tric and ilioinguinal nerves. Wolfson et al. found that bilateral IIIH nerve blocks using a standardized multi-level injection technique, previously devel-oped by bell et al. (149), result in lower resting VAS pain scores, lower analgesic requirements and greater satisfaction following cesarean delivery in patients who received neuraxial morphine (145). Despite evidence of efficacy, IIIH nerve blocks have a relatively short duration of action. This con-stitutes a major limitation to their widespread use. A continuous technique has been described, with ex-cellent results, in a small case series (150), but these encouraging data require further investigation.
Wound infiltration
Local anesthetic drugs are increasingly admin-istered through the wound following different types of surgery, including gynecological and obstetric procedures, with variable results. This is probably due to differences among studies in catheter placement sites, doses of medications, continuous or intermittent bolus mode of administration, and definition of outcomes. The administration of local anesthetic agents under the fascia has been shown to be more effective than the administration above it (151). ranta et al. compared epidural analgesia with wound catheters placed under the fascia and receiving intermittent boluses (152). They showed that, during the first 4 postoperative hours, the epi-dural patients achieved significantly better pain re-lief, and lower consumption of levobupivacaine. After four hours however, there were no significant differences between the sub-fascia and epidural group regarding pain scores, overall opioid con-sumption, patient satisfaction and side effects. o’neIll et al. tested a ropivacaine continuous wound infusion regimen and found lower postoper-ative median pain scores at 2-, 6- and 48-hour when compared to the epidural morphine control-group (153). In contrast, kaInu et al. found no
been demonstrated at clinically relevant doses (139). Ketamine is avidly transferred from the placenta, yet intravenous doses up to 2 mg/kg do not lead to reduced Apgar scores in the neonate (136). To our knowledge, no data on its transfer in human breast milk have been published so far.
Gabapentin
The perioperative use of gabapentin has been shown to decrease postoperative pain after various surgical procedures (140), including total hysterec-tomy (141). Recently, Moore et al. investigated its use for the management of post-cesarean delivery pain (142). The results of their randomized con-trolled trial suggest that, even in the setting of a multimodal regimen that includes intrathecal mor-phine, intrathecal fentanyl, oral paracetamol, oral diclofenac and systemic opioids for breakthrough pain, a single 600 mg oral dose of gabapentin given 1 hour before cesarean section significantly lowers pain scores during the first 48 postpartum hours and increases maternal satisfaction. Gabapentin is thought to exert its analgesic effect by binding to presynaptic voltage gated calcium channels in the dorsal root ganglia of the spinal cord, where it in-hibits the release of excitatory neurotransmit-ters (140). Gabapentin has also been shown to en-hance the analgesic effect of morphine in humans (143). Despite readily crossing through the placenta and transfer to the fetus, no increased risks for adverse fetal or neonatal outcomes (such as low birth weight or malformations) have been attributed to the use of gabapentin during pregnancy (144). The results of the study of Moore et al. are very encouraging, but further research is required to pro-vide information on the optimal dose and timing of gabapentin administration during the peri-operative period of a cesarean section.
local anesthetIc technIques targetIng perIpheral nerVe afferents
A significant component of pain after cesarean delivery arises from the surgical incision through the anterior abdominal wall. Multiple local anes-thetic techniques targeting peripheral nerve affer-ents, including ilioinguinal and iliohypogastric (IIIH) nerve blocks, wound instillation and, most recently, transversus abdominis plane (TAP) blocks, have been used to address this somatic component of post-cesarean section pain (145). The potential advantages of these techniques are their lower inva-
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tip within the transversus abdominis fascia plane. After careful aspiration to exclude vascular punc-ture, a local anesthetic solution can be injected there. It will block the sensory nerves of the anterior abdominal wall before they leave this plane to in-nervate the entire anterior abdominal wall (157). This ‘blind’ TAP block technique is easy to per-form, and safe (156, 158). However, the triangle of Petit may be difficult to palpate in obese pa-tients (156). TAP blocks also carry the risk of an unintentional peritoneal puncture (159). To reduce risks, the use of ultrasounds is a promising approach (148). In addition, ultrasound guidance reduces the time and number of attempts needed to perform the block, as well as the onset time (148).
In 50 women undergoing elective cesarean de-livery, Mcdonnell et al. compared a ropivacaine 0.75% (1.5 mg/kg to a maximum of 150 mg per side) TAP block and a saline placebo one. Standard postoperative analgesia including IV-PCA mor-phine, diclofenac and paracetamol was otherwise provided to all patients (158). The TAP blocks with local anesthetic agents reduced overall postopera-tive morphine requirements by more than 70% dur-ing the first 48 postoperative hours (Fig. 9). This finding is of importance, because it demonstrates that a single-shot TAP technique can produce effec-tive analgesia for up to 2 days. The reasons for this prolonged duration of analgesia are related to the relatively poor vascularization of the tranverse ab-dominis plane. Drug clearance from that space is therefore slow. A recent meta-analysis (160) dem-onstrates that TAP blocks significantly improve
benefit of a sub-fascia ropivacaine continuous wound infusion after cesarean delivery (154).
Local anesthetic injections into the wound work through a direct inhibition of noxious impulses from the site of injury. Another approach to modu-late peripheral nociceptive transmission consists in reducing the local expression of mediators that sensitize nociceptors on afferent fibers. Among these, prostaglandins are potent sensitizing agents. Their release is due to an increased cyclo-oxygen-ase (COX) expression in immune cells and fibro-blasts at the site of injury. A continuous diclofenac infusion (300 mg over 48 hours) through a wound infusion catheter appears to be as effective as a local ropivacaine infusion associated to the same dose of systemic diclofenac (300 mg administered as an intermittent intravenous bolus) (155).
Despite the fact that wound infusion catheters provide prolonged drug delivery, the relatively high cost of the disposable devices and the effort required for the preparation and insertion of those catheters may have limited their widespread acceptance.
Transversus abdominis plane (TAP) block
The transversus abdominis plane (TAP) block, whose popularity is growing, is a relatively new technique. It targets the neural afferents of the ante-rior abdominal wall. The TAP block was first de-scribed in 2001 by rafI (156) and was further de-veloped and tested by Mcdonnell et al. in 2007 (157). The lumbar triangle of Petit is used as an easy palpable landmark for injecting local anes-thetic agents into the neurovascular plane of the ab-dominal wall. That plane is located between the in-ternal oblique and the transversus abdominis muscles. Nerves supplying the anterior abdominal wall are derived from the T6 to L1 roots, and pass through this plane before supplying the muscles of the anterior abdominal wall. The triangle of Petit is posteriorly bounded by the latissimus dorsi muscle, anteriorly by the external oblique, and inferiorly by the iliac crest. The floor of the triangle is made of fascia extensions of both the external and the inter-nal oblique muscles (Fig. 8). In this triangle, a blunt regional anesthesia needle can be inserted perpen-dicular to the skin, immediately above the iliac crest, and behind the mid-axillary line. The trans-versus abdominis fascia plane is localized using a two-‘pop’ sensation (or loss of resistance) tech-nique. The first ‘pop’ indicates penetration of the fascia of the external oblique muscle and the second ‘pop’ indicates penetration of the internal oblique muscle, thereby indicating a position of the needle
Fig. 8. — Cross-section of the abdominal wall layers. The TAP block is performed by deposition of local anesthetic between the transversus abdominis muscle and the fascial layer super-ficial to it.Adapted from : McDonnell N. J., et al., anaesth. analg., 106, 186-191, 2008.
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when compared with their systemic administration. Neuraxial adjuvants (particularly clonidine and, to a lesser degree, epidural neostigmine) enhance post-cesarean section analgesia with few adverse effects apart from sedation. The use of these neuraxial drugs is not yet widely spread. In addition to opi-oids, systemic non-opioid analgesic agents such as paracetamol, NSAIDs, ketamine, and gabapentin may add further benefit. Among the local anesthetic techniques targeting peripheral nerve afferents, the TAP block is particularly promising. It has shown excellent results in multiple randomized controlled trials. In summary, a multimodal approach is rec-ommended whenever possible, to maximize pain relief while minimizing untoward effects.
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conclusIon
Adequate pain relief is essential after cesarean section to promote early recovery and early mater-nal care for the newborn. However, there is no ‘gold standard’ for post-caesarean pain management. The number of options is large (see also Table 1). The choice between one method or the other is at least partly determined by drug availability, regional and individual preferences, resource limitations, and fi-nancial considerations. Most methods rely on opi-oids, supplemented with anti-inflammatory analge-sic agents, nerve blocks or other adjunctive techniques. Spinal and epidural opioids appear to have a favorable efficacy and adverse-effect profile
Fig. 9. — A box plot of postoperative cumulative morphine consumption in each group in the first 48 postoperative hours. The middle line in each box represents the median value, the outer margin of the box represent the interquartile range, and the whiskers represent the 10th and 90th percentile for each time point. *Indicates significantly higher morphine consump-tion compared with the transverses abdominis plane (TAP) block group (P < 0.05, Wilcoxon’s ranked sum test).Adapted from : McDonnell N. J., et al., anaesth. analg., 106, 186-191, 2008.
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