BACKGROUND: Alkaptonuria (AKU) is an inborn error of catabolism due to a deficient activity of homogentisate 1,2-dioxygenase. Patients suffer from a severe arthropathy, cardiovascular and kidney disease but other organs are affected, too. We found secondary amyloidosis as a life-threatening complication in AKU, thus opening new perspectives for its treatment. We proved that methotrexate and anti-oxidants have an excellent efficacy to inhibit the production of amyloid in AKU model chondrocytes. Owing to the progressive and intractable condition, it seems important to detect amyloid deposits at an early phase in AKU and the choice of specimens for a correct diagnosis is crucial. METHODS: Ten AKU subjects were examined for amyloidosis; abdominal fat pad aspirates, labial salivary gland, cartilage and synovia specimens were analysed by CR, Th-T, IF, TEM. RESULTS: Amyloid was detected in only one abdominal fat pad specimen. However, all subjects demonstrated amyloid deposition in salivary glands and in other organ biopsies, indicating salivary gland as the ideal specimen for early amyloid detection in AKU. CONCLUSIONS: This is, at the best of our knowledge, the first report providing correct indications on the diagnosis of amyloidosis in AKU, thus offering the possibility of treatment of such co-morbidity to AKU patients. VIRTUAL SLIDES: The virtual slide(s) for this article can be found here: http://www.diagnosticpathology.diagnomx.eu/vs/13000_2014_185.
BACKGROUND: Alkaptonuria (AKU) is an inborn error of catabolism due to a deficient activity of homogentisate 1,2-dioxygenase. Patients suffer from a severe arthropathy, cardiovascular and kidney disease but other organs are affected, too. We found secondary amyloidosis as a life-threatening complication in AKU, thus opening new perspectives for its treatment. We proved that methotrexate and anti-oxidants have an excellent efficacy to inhibit the production of amyloid in AKU model chondrocytes. Owing to the progressive and intractable condition, it seems important to detect amyloid deposits at an early phase in AKU and the choice of specimens for a correct diagnosis is crucial. METHODS: Ten AKU subjects were examined for amyloidosis; abdominal fat pad aspirates, labial salivary gland, cartilage and synovia specimens were analysed by CR, Th-T, IF, TEM. RESULTS: Amyloid was detected in only one abdominal fat pad specimen. However, all subjects demonstrated amyloid deposition in salivary glands and in other organ biopsies, indicating salivary gland as the ideal specimen for early amyloid detection in AKU. CONCLUSIONS: This is, at the best of our knowledge, the first report providing correct indications on the diagnosis of amyloidosis in AKU, thus offering the possibility of treatment of such co-morbidity to AKU patients. VIRTUAL SLIDES: The virtual slide(s) for this article can be found here: http://www.diagnosticpathology.diagnomx.eu/vs/13000_2014_185.
Amyloidosis is the deposition of insoluble protein aggregates either
systemically or in a specific organ. Secondary (AA) amyloidosis is caused by a
chronic infection or chronic inflammatory disease where deposits are made up of
serum amyloid A (SAA) produced during inflammation.We found SAA amyloidosis as a life-threatening complication in
alkaptonuria (AKU) [1], an ultra-rare
(1:250.000-1.000.000 incidence) autosomal recessive genetic disease due to a
deficient activity of homogentisate 1,2-dioxygenase (HGD) leading to the
accumulation of homogentisic acid (HGA). HGA-oxidized derivative benzoquinone acetic
acid (BQA) forms deposits in the connective tissue, causing a pigmentation known as
“ochronosis”, leading to dramatic organ damage. A severe form of arthropathy is the
most common clinical presentation of AKU, but all the organs can be affected, too.
AKU can be treated symptomatically during the early stages, whereas for end stages
total joint and heart valve replacements may be required. Currently, there is no
therapy for AKU, although a clinical trial with nitisinone is in progress.AA amyloidosis is one of the most severe complications of several
chronic rheumatic disorders [2,3] and is a secondary
complication of AKU due to a chronic inflammatory status derived from
HGA/BQA-induced oxidative stress [4-12]. SAA-amyloid in
AKU co-localizes with ochronotic pigment [1], AKU is a complicated inflammatory multisystemic disease, and
any body district expressing HGD may be affected
[13].Our findings on AKU as a novel AA amyloidosis opened new perspectives
for its treatment. In fact, the suppression of SAA below 10 mg/L halts the
progression of the disease and is associated with prolonged survival, reversal of
amyloid deposition and recovery of organ function [14]. Methotrexate [1]
and anti-oxidants [9] proved to have an
excellent efficacy to inhibit the production of amyloid in AKU model chondrocytes,
suggesting their introduction in AKU therapy.Owing to AKU progressive and intractable condition, it is crucial to
detect amyloid deposits at an early phase. As ascertained in other secondary
amyloidosis, if SAA deposition cannot be stopped or delayed, serious
life-threatening problems can arise [14]. Therefore, SAA amyloidosis should be diagnosed as early as
possible and the clinicians treating AKU patients need an easy routine reproducible
fast procedure that can be repeated at intervals.In this work, ten AKU subjects were examined for amyloidosis in
abdominal fat pad aspirates and labial salivary gland (LSG) biopsies. Amyloid was
detected in only one abdominal fat pad specimen. However, all subjects demonstrated
amyloid deposition in LSGs and in other organ biopsies. These results further
support the concept that LSG may be the optimal specimen for early detection of
amyloid in AKU and that LSG offers improved sensitivity in respect to fat pad
aspirates in these patients.This is, at the best of our knowledge, the first report providing
correct indications on the diagnosis of amyloidosis in AKU, thus offering the
possibility of treatment of such co-morbidity to AKU patients.
Methods
Procedures were approved by Siena University Hospital and national
Ethics (Comitato Etico Policlinico Universitario di Siena, number GGP10058, date
21/07/2010) in accordance with 1975 Helsinki Declaration, revised in 2000 (52nd WMA
General Assembly, Edinburgh, Scotland, October 2000). Informed consent was obtained
from all patients.All reagents were from Sigma-Aldrich (St. Louis, MO), if not
differently specified.
LSG
After reviewing AKU patients’ medical history and laboratory values
(Table 1 and 2), a clinical examination was completed and each subject
underwent two biopsies of clinically normal-appearing tissue in the oral cavity
under local anesthesia (2% lidocaine with 1:100,000 epinephrine). Specimen 1 was
taken from the left lateral surface of the tongue, containing mucosal and muscle
tissue. Specimen 2 was taken from the labial mucosa on the left side of the lower
lip, containing at least 2 to 3 minor salivary glands. Both specimens were
formalin fixed and analyzed for histopathologic evaluation of amyloid.
Table 1
Alkaptonuria patients enrolled for the study and
their characteristics
Features
Patient 1
Patient 2
Patient 3
Patient 4
Patient 5
Patient 6
Patient 7
Patient 8
Patient 9
Patient 10
Age (years)
71
60
63
42
60
58
42
38
65
55
Sex
F
F
F
F
M
M
M
F
F
F
Serology
SAA mg/L
117.70
87.14
97.44
18.16
25.35
25.44
25.13
16.13
28.46
69.90
HGA plasma level μmol/L
31.10
72.90
20.56
15.80
17.02
22.43
18.95
15.21
31.76
13.42
HGA urine level mmol/L
23.70
16.90
22.64
21.70
22.30
18.64
24.10
12.68
22.76
16.60
Congo Red birefringence score
Abdominal fat
n.d.
-
-
-
-
-
-
-
n.d.
+
Salivary gland
+++
++
++
++
++
+++
++
+++
++
++
Synovia
+++
Cartilage
+++
+++
Aortic valve
+++
+++
Prostatic stone
++
ThT fluorescence (+/−)
Salivary gland
positive
positive
positive
positive
positive
positive
positive
positive
positive
positive
Synovia
positive
positive
Cartilage
positive
positive
Aortic valve
positive
Prostatic stone
n.d.
SAA immunohistology (+/−)
Salivary gland
positive
positive
positive
positive
positive
positive
positive
positive
positive
positive
Synovia
positive
positive
positive
positive
Cartilage
positive
positive
positive
positive
positive
Prostatic stone
positive
Aortic valve
positive
SAP immunohistology (+/−)
Salivary gland
positive
positive
positive
positive
positive
positive
positive
positive
positive
positive
Synovia
positive
positive
Cartilage
positive
positive
Aortic valve
positive
Prostatic stone
positive
TEM Amyloid abundance score
+++
+++
++
+++
+++
+++
++
+++
++
+
F: female, M: male, n.d.: not determined. The patients were
classified on the basis of Congo red intensity of staining (grades: +++,
very intensive; ++, intensive; +, weak; −, no birefringence). The presence
of amyloid deposits in LSG observed at TEM was evaluated as: +++ = very
abundant, ++ = medium; + = faint. Positivity for ThT fluorescence and SAA
and SAP immunohistology is also reported.
Table 2
Clinical features of AKU patients
Patient #
Date of selection (month/year)
Peripheral neuropathy
Orthostatic hypotension
Ventricular and atrial dilatation
chronic bacterial infection
Spondylarthropathy
Glossomegaly
Surgery
1
08/2011
y
y
y
n
y
y
Knee (r), shoulder (r) and hip (l) arthroplasty
2
10/2009
y
y
n
y
y
n
Knee (r, l), shoulder (r) and hip (r)
arthroplasty
3
03/2012
n
y
n
n
y
n
Meniscus (r) surgical repair
4
04/2012
y
y
n
n
n
n
None
5
11/2012
y
y
n
y
y
n
Knee (l), and hip (l) arthroplasty
6
01/2013
y
n
n
y
y
n
Knee (r) arthroplasty
7
05/2012
n
y
n
n
n
n
None
8
02/2012
y
y
y
n
y
n
Knee (l) arthroplasty
9
03/2013
y
n
y
y
y
y
Knee (r) and tendon ankle fracture (l)
10
11/2011
y
y
n
n
y
y
Knee (r), and hip (l) arthroplasty
No patient was receiving immunosuppressive or chemotherapy
treatment. y = yes; n = no; r = right; l = left.
Alkaptonuria patients enrolled for the study and
their characteristicsF: female, M: male, n.d.: not determined. The patients were
classified on the basis of Congo red intensity of staining (grades: +++,
very intensive; ++, intensive; +, weak; −, no birefringence). The presence
of amyloid deposits in LSG observed at TEM was evaluated as: +++ = very
abundant, ++ = medium; + = faint. Positivity for ThT fluorescence and SAA
and SAP immunohistology is also reported.Clinical features of AKU patientsNo patient was receiving immunosuppressive or chemotherapy
treatment. y = yes; n = no; r = right; l = left.
Abdominal fat
Patients underwent a subcutaneous abdominal fat biopsy via
fine-needle aspiration. Skin and subcutaneous tissue around the umbilicus of the
patients were anesthetized with 1% lidocaine. The fat was aspirated with an
18-gauge needle connected to a 20 ml syringe. At least two visible fragments of
fat were placed on a glass slide and crushed into a single layer by pressing a
second slide against the first. After the smears were dried in air at 50°C for at
least 30 minutes and fixed with 20% formalin neutral buffer solution (Wako Pure
Chemical, Osaka, Japan) for 5 minutes, these specimens were processed for the
Congo Red staining.
Cartilage and synovia
Articular cartilage fragments, from AKU subjects who underwent
surgery for joint replacement, were placed in 5% formaldehyde. Samples were
alcohol dehydrated and paraffin embedded.
Aortic valve
Valve was obtained from an AKU subject who underwent biologic
aortic valve replacement.
Prostatic calculus
The stone was from the prostate gland of an AKU subject who
underwent surgical exploration for calculus removal.
Hematoxylin and Eosin (H&E) staining
Two sections (5 μm thickness) were obtained from each biopsy.
Sections were stained with traditional hematoxylin/eosin (H/E) staining.
Congo Red (CR) staining
Romhányi’s CR staining method modified according to Bély and Apáthy
(2000) was adopted. 5 μm sections of fresh specimen were fixed in cooled 96%
ethanol 10 min, rinsed in water, incubated in 1% CR for 40 min, washed in water,
incubated 10 s in 1 mL 1% sodium hydroxide in 100 mL of 50% ethanol, incubated
30 s in Mayer's hematoxylin, sequentially washed in 50%, 75%, 95% ethanol, mounted
and observed under a polarized light microscope (Zeiss Axio Lab.A1, Arese,
Milano).
Thioflavin T (Th-T) staining
AKU LSG samples incubated in 1% Th-T [15,16] were mounted and observed under a fluorescence microscope
(excitation 450 nm, emission 482 nm).
Fluorescence microscopy
AKU samples in paraffin were cut in 3–5 μm slices and double
immunofluorescence stained with anti-SAA and anti-serum amyloid P (SAP) antibodies
(Santa Cruz Biotechnology, CA). Nuclei were counter-stained with blue DAPI DNA
stain (Abcam, Cambrige, UK).
Transmission electron microscopy (TEM)
AKU specimens were fixed in 2.5% glutaraldehyde in 0.1 M cacodylate
buffer (CB) pH 7.2 for 3 h at 4°C, post-fixed in 1% osmium tetroxide in CB for
2 hours at 4°C, ethanol dehydrated and embedded in a mixture of Epon–Araldite
resins. Thin sections, obtained with a Reichert ultramicrotome, were stained with
uranyl acetate and lead citrate and observed with a TEM FeiTecnai G2 spirit at 80
Kv.
Results
Structural features of AKU salivary glands were first evaluated by
means of H&E staining (representative images are presented in
Figure 1A-B). Parenchyma was found to be
compact only in some limited areas; by contrast, a number of vacuoles and a
disrupted acinar structure were present in the vast majority of the specimen. All of
the AKU salivary glands that were examined did not contain any trace of lymphocytic
infiltration.
Figure 1
H/E staining of AKU salivary gland. Some
striated ducts (arrowheads), secretory acini (white arrows) and red blood
cells (black arrows) are indicated. Only representative images are shown.
Magnification: A: 20×; B: 40 × .
H/E staining of AKU salivary gland. Some
striated ducts (arrowheads), secretory acini (white arrows) and red blood
cells (black arrows) are indicated. Only representative images are shown.
Magnification: A: 20×; B: 40 × .In order to diagnose amyloidosis in AKU patients, diagnostic
laboratories adopted periumbelical fat aspirate CR staining [17] that unfortunately proved to be unsuitable for
the detection of amyloid deposits in AKU patients. Indeed, we studied abdominal fat
pad aspirates and labial salivary gland biopsies from 10 AKU patients in whom
subsequent other tissue biopsies for confirmation of AA amyloidosis were also
available. All cases were suspected to have SAA deposits, but nine of them had
negative results on abdominal fat pad aspirates evaluated by polarizing microscopy
of CR stained sections (not shown). CR staining of fat aspirates from three
different hospital laboratories were compared in all samples for studying inter
observer reproducibility and gave negative diagnosis of amyloidosis in nine cases
out of ten.Once CR staining was adopted on AKU LSGs, the results were
unequivocally positive for all ten patients (Figure 2A).
Figure 2
Evidence of amyloid deposits in AKU salivary
glands
A)
Congo Red staining of AKU labial salivary glands
amyloid deposits. CR stain viewed under polarized light
detected the presence of diffuse amyloid deposits within AKU salivary gland
tissue. Magnification 20×. Representative images from a triplicate set are
shown. B)
Th-T fluorescence of AKU labial salivary glands
amyloid deposits shown by confocal microscopy. Analogous
results were obtained from specimens of other patients. Bar: 22 μm.
Representative images from a triplicate set are shown.
Evidence of amyloid deposits in AKU salivary
glands
A)
Congo Red staining of AKU labial salivary glands
amyloid deposits. CR stain viewed under polarized light
detected the presence of diffuse amyloid deposits within AKU salivary gland
tissue. Magnification 20×. Representative images from a triplicate set are
shown. B)
Th-T fluorescence of AKU labial salivary glands
amyloid deposits shown by confocal microscopy. Analogous
results were obtained from specimens of other patients. Bar: 22 μm.
Representative images from a triplicate set are shown.To confirm the presence of amyloid aggregates in LSG from AKU
patients, we performed the Th-T assay. Th-T fluorescence was evident in all examined
samples (10/10) (Figure 2B). Moreover, by
means of immunofluorescence techniques, we assessed the presence of SAA deposition
in LSG (Figure 3).
Figure 3
SAA and SAP in AKU salivary glands
A)
Immunofluorescence staining of SAA deposition in AKU
labial salivary glands. Blue indicates DAPI stained nuclei.
Magnification 20×. Representative images from a triplicate set are shown.
B)
Immunofluorescence staining of SAP deposition in AKU
labial salivary glands. Magnification 20×. Representative
images from a triplicate set are shown.
SAA and SAP in AKU salivary glands
A)
Immunofluorescence staining of SAA deposition in AKU
labial salivary glands. Blue indicates DAPI stained nuclei.
Magnification 20×. Representative images from a triplicate set are shown.
B)
Immunofluorescence staining of SAP deposition in AKU
labial salivary glands. Magnification 20×. Representative
images from a triplicate set are shown.Ultrastructural analysis by TEM of AKU LSGs (the current ‘gold
standard’ for detecting amyloid deposits also in ambiguous cases), confirmed the
massive presence of amyloid fibrils in all specimens. Amyloid deposits in LSG were
abundant in six patients, moderate in three, and mild in one (Table 1). Figure 4
shows fine fibrils, approximately 10 nm in diameter, located in the secretory stroma
of AKU salivary glands of patient #1, adjacent to the basement membrane. The fibrils
were also present in the interstitial connective tissue, interspersed with collagen
fibrils (Figure 4A) and around interlobular
ducts of salivary glands of all patients. In all observed samples, the glandular
stroma contained numerous broken collagen fibrils strictly interconnected with
amyloid fibrils arranged in a scattered manner. Moreover, thanks to TEM analysis, it
was possible to see evident pigment traces finely sprinkled over the whole tissue
(Figure 4B-F). In particular, pigment
deposits could be seen as individual “drop-like” deposits between the collagen
fibers and also scattered over amyloid bundles of fibrils.
Figure 4
Electron micrographs of AKU salivary glands
A) Electron micrograph showing fine amyloid
fibrils (A) approximately 10 nm in diameter
located in close relation to the lamina (LP) of the secretory end-pieces as
well as in the interstitial connective tissue stroma of AKU labial salivary
gland. Pigment granules are visible amongst collagen fibrils in transverse
and longitudinal section (black arrows). B-C) Electron micrographs of another AKU labial salivary gland
showing a region of the interstitial glandular stroma that contains fine
amyloid fibrils (A), approximately 10 nm in
diameter, interspersed with bundles of collagen fibrils (C). Pigment deposits are present on broken
collagen fibers (black arrows) and scattered between amyloid fibrils. To be
note that amyloid fibrils appear superimposed to collagen fibers in
different area of the tissue. D-F) Electron
micrograph of a third AKU labial salivary gland showing the glandular stroma
containing finely fibrillar amyloid material (A). In photo E) collagen
fibers in transverse section are shown (arrowheads), many of which
presenting electron dense ochronotic deposits located amongst fibers. In
photos E-F), dark ochronotic pigment
granules are indicated (arrowheads) scattered amongst the collagen fiber as
well as amongst amyloid fibrils. Some deposits can be observed located
within amyloid bundles of fibrils and bridging between collagen fibers
(white arrows). A: amyloid; C: collagen; LP lamina propria. Photo A is from patient #2, photos B-C are from patient #5 and photos D-F are from patient #7. Bars, A: 5 μm, B, C and E: 2.5 μm, D and
F: 1 μm.
Electron micrographs of AKU salivary glands
A) Electron micrograph showing fine amyloid
fibrils (A) approximately 10 nm in diameter
located in close relation to the lamina (LP) of the secretory end-pieces as
well as in the interstitial connective tissue stroma of AKU labial salivary
gland. Pigment granules are visible amongst collagen fibrils in transverse
and longitudinal section (black arrows). B-C) Electron micrographs of another AKU labial salivary gland
showing a region of the interstitial glandular stroma that contains fine
amyloid fibrils (A), approximately 10 nm in
diameter, interspersed with bundles of collagen fibrils (C). Pigment deposits are present on broken
collagen fibers (black arrows) and scattered between amyloid fibrils. To be
note that amyloid fibrils appear superimposed to collagen fibers in
different area of the tissue. D-F) Electron
micrograph of a third AKU labial salivary gland showing the glandular stroma
containing finely fibrillar amyloid material (A). In photo E) collagen
fibers in transverse section are shown (arrowheads), many of which
presenting electron dense ochronotic deposits located amongst fibers. In
photos E-F), dark ochronotic pigment
granules are indicated (arrowheads) scattered amongst the collagen fiber as
well as amongst amyloid fibrils. Some deposits can be observed located
within amyloid bundles of fibrils and bridging between collagen fibers
(white arrows). A: amyloid; C: collagen; LP lamina propria. Photo A is from patient #2, photos B-C are from patient #5 and photos D-F are from patient #7. Bars, A: 5 μm, B, C and E: 2.5 μm, D and
F: 1 μm.Our study showed, for the first time, that, analogously to other AKU
tissues [1,9], also in LSG amyloid and pigment were strictly interconnected
and that collagen fibrils seemed to feel the effect of destructive action of both
pigment and amyloid, appearing constantly broken and damaged when sprinkled and
invaded by these two elements. The presence of ochronotic pigmentation in less
commonly examined areas of human body, such as glandular tissues, may provide
insights into the mechanisms of pigment formation and deposition. Here, we presented
evidence to support the probable association of HGA oxidised products with collagen
and the existence of extracellular mechanisms, like as amyloid deposition, mediating
ochronotic pigmentation that overlaps in tissues.Confirmatory evaluation of SAA- and SAP-amyloid co-presence
(Figure 5A) and TEM observation of amyloid
fibrils (Figure 5B) in other AKU specimens
was possible.
Figure 5
Confirmation of amyloidosis in other AKU
tissues
A) Positive staining for SAA-and
SAP-amyloid in cartilage, synovia, aortic valve and prostatic stone.
B) TEM observation of amyloid deposits in
cartilage (left image: bar 500 nm) and aortic valve (right image: bar
50 nm).
Confirmation of amyloidosis in other AKU
tissues
A) Positive staining for SAA-and
SAP-amyloid in cartilage, synovia, aortic valve and prostatic stone.
B) TEM observation of amyloid deposits in
cartilage (left image: bar 500 nm) and aortic valve (right image: bar
50 nm).
Discussion
The tissue source impacts the likelihood of discovering amyloid
deposits. Bone marrow biopsy sensitivity has been estimated at 63% [18]. Kidney, liver, or cardiac biopsies have
sensitivity as high as 87–98% but are more invasive [18]. Rectal biopsy sensitivity ranges from 69% to 97% depending
upon the quantity of tissue sampled. Tissue source also impacts amyloid typing. The
chemical type of amyloid that deposits in AKU is amyloid A protein and since this
type of amyloid involves diffusely the mucosa and the submucosa [19], it may be better to prefer location as the
oral cavity or gastrointestinal tract to detect them. In particular, LSG biopsy is
less invasive and cheaper than examination of rectal mucosa. In the last years,
various studies have demonstrated the utility of LSG biopsy for the detection of
amyloid with correlation to secondary systemic amyloidosis [20,21].Amyloid deposition is a dynamic process that can progress and
stabilize. Quantification of SAA concentration in tissue on regular occasions will
similarly reflect the accumulation, stabilization or even regression of deposited
amyloid. Abdominal subcutaneous fat tissue seems to be very suitable for this
purpose [17,22], because it is easy to obtain by aspiration,
but, at least in some cases, it has limited sensitivity and turned out inadequate
[23-25]. In fact, subcutaneous abdominal fat CR staining is positive in
approximately 80% of patients with AL amyloidosis and less than 65% of patients with
AA amyloidosis [24]. Thus, the negative
result on staining of the abdominal-fat aspirate in AKU cases does not necessarily
indicate negativity of amyloidosis at the diagnosis. Moreover, Tribe [26] did not recommend the use of subcutaneous fat
aspiration because he reported that “fat is rarely involved”. Libbey et al.
[17] reported a 20% false negative
result rate. It thus appears that abdominal fat aspiration is a method not enough
sensitive to detect AA in rheumatic diseases.In all ten AKU samples, amyloid deposits were identified so
underlining the high sensitivity of LSG biopsy in the diagnosis of amyloidosis, even
in the absence of other symptoms.
Conclusions
LSG biopsy appears as a simple and safe method to detect generalized
amyloidosis in patients with a chronic inflammatory disease such as AKU. The results
of our pilot study demonstrate that the prevalence of occult amyloid deposition in
patients with AKU may be very high. Since a prompt detection of amyloid may have
significant clinical and economic implications in AKU, it is fundamental to
establish accurately the association of synchronous amyloidosis. In our limited size
sample, due to ultra-rarity of the disease, the majority of AKU patients had no
detectable amyloid deposition on fat pad aspirate. However, we were able to detect
amyloid deposition in minor LSG in all AKU patients. This suggests that subclinical
amyloid deposition may be more easily detected on oral biopsies, and the oral cavity
may be the preferred biopsy site for detecting amyloid deposition in AKU patients
with no symptoms of systemic amyloidosis.Our study suggests that minor LSG, especially when the biopsy of
affected are lacking, may be the gold standard for the diagnosis of SAA amyloidosis
in AKU.
Authors: Laura Tinti; Adam M Taylor; Annalisa Santucci; Brenda Wlodarski; Peter J Wilson; Jonathan C Jarvis; William D Fraser; John S Davidson; Lakshminarayan R Ranganath; James A Gallagher Journal: Rheumatology (Oxford) Date: 2010-10-15 Impact factor: 7.580
Figure 1
Figure 2
Figure 3
Figure 4
Figure 5