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Australian Armourers
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BERYLLIUM DISEASE*
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|
Formula |
Specific |
Melting/boiling point ( |
Solubility |
Description |
|
Beryllium (Be) |
9.01 (a.w.) |
1.85 |  |
- |
Grey to silver metal |
|
Beryllium oxide (BeO) |
25 |
3.02 |  |
Soluble in acids and alkalis; insoluble in water |
White amorphous powder |
|
Beryllium |
47.02 |
1.99 |
Sublimes 800 |
Readily soluble in water; sparingly soluble in ethyl alcohol |
Hygroscopic solid |
|
Beryllium |
79.9 |
1.90 |
405/520 |
Very soluble in water; soluble in ethyl alcohol, benzene, ethyl ether and carbon disulphide |
White or slightly yellow deliquescent crystals |
|
Beryllium |
187.08 |
1.56 |
60/142 |
Soluble in water and ethyl alcohol |
White to faintly yellow deliquescent crystals |
|
Beryllium |
55.06 |
- |  |
- |
Hard, refractory white crystals |
|
Beryllium sulphate |
177.2 |
1.71 |
100/- |
Soluble in water; insoluble in ethyl alcohol |
Colourless crystals(( |
Beryllium fluoride is made by the decompensation at 900-950 
of ammonium beryllium fluoride. Its main use is in the production of beryllium metal by reduction with magnesium.
Beryllium chloride is manufactured by passing chlorine over a mixture of beryllium oxide and carbon.
Beryllium nitrate is produced by the action of nitric acid on beryllium
oxide. It is used as a chemical reagent and as a gas mantle hardener.
Beryllium nitride is prepared by heating beryllium metal powder in an oxygen-free, nitrogen atmosphere at 700-1,400 
. It is used in atomic energy reactions, including the production of the radioactive carbon isotope carbon-14.
Beryllium sulphate hydrate is produced by treating the fritted ore with
concentrated suphuric acid. It is used in the production of metallic
beryllium by the sulphate process.
___________________________________________________________________________
Sources
Beryl 
is the chief commercial source of beryllium, the most abundant of the
minerals containing high concentrations of beryllium oxide (10 to 13%).
Major sources of beryl are to be found in Argentina, Brazil, India,
Zimbabwe and the Republic of South Africa. In the United States, beryl
is found in Colorado, South Dakota, New Mexico and Utah. Bertrandite, a
low-grade ore (0.1 to 3%) with an acid-soluble beryllium content, is
now being mined and processed in Utah.
Production
The two most important methods of extracting beryllium from the ore are the sulphate process and the fluoride process.
In
the sulphate process, crushed beryl is melted in an arc furnace at
1,650C and poured through a high-velocity water stream to form a frit.
After heat treatment, the frit is ground in a ball mill and mixed with
concentrated sulphuric acid to form a slurry, which is sprayed in the
form of a jet into a directly heated, rotating sulphating mill. The
beryllium, now in a water-soluble form, is leached from the sludge, and
ammonium hydroxide is added to the leach liquor, which is then fed to a
crystallizer where ammonium alum is crystallized out. Chelating agents
are added to the liquor to hold iron and nickel in solution, sodium
hydroxide is then added, and the sodium beryllate thus formed is
hydrolyzed to precipitate beryllium hydroxide. The latter product may
be converted to beryllium fluoride for reduction by magnesium to
metallic beryllium, or to beryllium chloride for electrolytic reduction.
In
the fluoride process (figure 10.11) a briquetted mixture of ground ore,
sodium silicofluoride and soda ash is sintered in a rotating hearth
furnace. The sintered material is crushed, milled and leached. Sodium
hydroxide is added to the solution of beryllium fluoride thus obtained
and the precipitate of beryllium hydroxide is filtered in a rotary
filter. Metallic beryllium is obtained as in the previous process by
the magnesium reduction of beryllium fluoride or by electrolysis of
beryllium chloride.
___________________________________________________________________________
Figure 10.11 Production of beryllium oxide by the fluoride process
___________________________________________________________________________
Uses
Beryllium is used in alloys with a number of metals including steel,
nickel, magnesium, zinc and aluminium, the most widely used alloy being
beryllium-copper-properly called “a bronze”-which has a high tensile
strength and a capacity for being hardened by heat treatment. Beryllium
bronzes are used in non-spark tools, electrical switch parts, watch
springs, diaphragms, shims, cams and bushings.
One
of the largest uses of the metal is as a moderator of thermal neutrons
in nuclear reactors and as a reflector to reduce the leakage of
neutrons from the reactor core. A mixed uranium-beryllium source is
often used as a neutron source. As a foil, beryllium is used as window
material in x-ray tubes. Its lightness, high elastic modulus and heat
stability make it an attractive material for the aircraft and aerospace
industry.
Beryllium oxide is made by heating beryllium nitrate or hydroxide.
It
is used in the manufacture of ceramics, refractory materials and other
beryllium compounds. It was used for the manufacture of phosphors for
fluorescent lamps until the incidence of beryllium disease in the
industry caused its use for this purpose to be abandoned (in 1949 in
the United States).
Hazards
Fire and health hazards are associated with processes involving
beryllium. Finely divided beryllium powder will burn, the degree of
combustibility being a function of particle size. Fires have occurred
in dust filtration units and during the welding of ventilation ducting
in which finely divided beryllium was present.
Beryllium
and its compounds are highly toxic substances. Beryllium can affect all
organ systems, although the primary organ involved is the lung.
Beryllium causes systemic disease by inhalation and can distribute
itself widely throughout the body after absorption from the lungs.
Little beryllium is absorbed from the gastro-intestinal tract.
Beryllium can cause skin irritation and its traumatic introduction into
subcutaneous tissue can cause local irritation and granuloma formation.
Pathogenesis
Beryllium in all its forms, except for beryl ore, has been associated
with disease. The route of entry is by inhalation and in the acute
disease there is a direct toxic effect on both the nasopharyngeal
mucosa and that of the entire tracheobronchial tree as well, causing
oedema and inflammation. In the lung it causes an acute chemical
pneumonitis. The major form of beryllium toxicity at this point in time
is chronic beryllium disease. A beryllium-specific delayed type of
hypersensitivity is the major pathway of chronic disease. The entry of
beryllium into the system through the lungs leads to proliferation of
specific 
lymphocytes, with beryllium acting as a specific antigen, either alone
or as a hapten through an interleukin-2 (IL2) receptor pathway.
Individual susceptibility to beryllium thus can be explained on the
basis of the individual 
response. Release of lymphokines from the activated lymphocytes then
can lead to granuloma formation and macrophage recruitment. Beryllium
can be transported to sites outside the lung where it can cause
granuloma formation. Beryllium is released slowly from different sites
and it is excreted by the kidneys. This slow release can occur over a
span of 20 to 30 years. The chronicity and latency of disease can
probably be explained on the basis of the slow metabolism and release
phenomenon. The immune mechanisms involved in the pathogenesis of
beryllium disease also allow for specific approaches to diagnosis,
which will be discussed below.
Histopathology
The primary pathological finding in beryllium disease is the formation
of non-caseating granulomas in the lungs, lymph nodes and at other
sites. Histopathological studies of lungs in patients with acute
beryllium disease have shown a non-specific pattern of acute and
subacute bronchitis and pneumonitis. In chronic beryllium disease,
there are varying degrees of lymphocytic infiltration of the lung
interstitium and non-caseating granuloma formation (figure 10.12).
___________________________________________________________________________
Figure 10.12 Lung tissue in a patient with chronic beryllium disease
Both granulomas and round cell infiltration are visible
___________________________________________________________________________
Many of the granulomas are located in the peribronchiolar areas. In
addition, there can be histiocytes, plasma cells and giant cells with
calcific inclusion bodies. If it is a case solely of granuloma
formation, the long-term prognosis is better. The histology of the lung
in chronic beryllium disease is indistinguishable from that of
sarcoidosis. Non-caseating granulomas are also found in lymph nodes,
liver, spleen, muscle and skin.
Clinical Manifestations
Skin injuries
Acid salts of beryllium cause allergic contact dermatitis. Such lesions
may be erythematous, papular or papulovesicular, are commonly pruritic,
and are found on exposed parts of the body. There is usually a delay of
2 weeks from first exposure to occurrence of the dermatitis, except in
the case of heavy exposures, when an irritant reaction may be
immediate. This delay is regarded as the time required to develop the
hypersensitive state.
Accidental
implantation of beryllium metal or crystals of a soluble beryllium
compound in an abrasion, a crack in the skin or under the nail may
cause an indurated area with central suppuration. Granulomas can also
form at such sites.
Conjunctivitis and dermatitis may occur alone or together. In cases of conjunctivitis, periorbital oedema may be severe.
Acute disease
Beryllium nasopharyngitis is characterized by swollen and hyperaemic
mucous membranes, bleeding points, fissures and ulceration. Perforation
of the nasal septum has been described. Removal from exposure results
in reversal of this inflammatory process within 3 to 6 weeks.
Involvement
of the trachea and bronchial tree following exposure to higher levels
of beryllium causes non-productive cough, substernal pain and moderate
shortness of breath. Rhonchi and/or rales may be audible, and the x ray
of the chest may show increased bronchovascular markings. The character
and speed of onset and the severity of these signs and symptoms depend
on the quality and quantity of exposure. Recovery is to be expected
within 1 to 4 weeks if the worker is removed from further exposure.
The
use of steroids is quite useful in countering the acute disease. No new
cases of acute disease have been reported to the US Beryllium Case
Registry in over 30 years. The Registry, which was started by Harriet
Hardy in 1952, has almost 1,000 case records, among which are listed
212 acute cases. Almost all of these occurred in the fluorescent lamp
manufacturing industry. Forty-four subjects with the acute disease
subsequently developed chronic disease.
Chronic beryllium disease
Chronic beryllium disease is a pulmonary and systemic granulomatous
disease caused by inhalation of beryllium. The latency of the disease
can be from 1 to 30 years, most commonly occurring 10 to 15 years after
first exposure. Chronic beryllium disease has a variable course with
exacerbations and remissions in its clinical manifestations. However,
the disease is usually progressive. There have been a few cases with
chest x-ray abnormalities with a stable clinical course and without
significant symptoms.
Exertional
dyspnoea is the most common symptom of chronic beryllium disease. Other
symptoms are cough, fatigue, weight loss, chest pain and arthralgias.
Physical findings may be entirely normal or may include bibasilar
crackles, lymphadenopathy, skin lesions, hepatosplenomegaly and
clubbing. Signs of pulmonary hypertension may be present in severe,
long-standing disease.
Renal stones and hyperuricaemia can occur
in some patients and there have been rare reports of parotid gland
enlargement and central nervous system involvement. The clinical
manifestations of chronic beryllium disease are very similar to those
of sarcoidosis.
Roentgenologic features
The x-ray pattern in chronic beryllium disease is non-specific and is
similar to that which may be observed in sarcoidosis, idiopathic
pulmonary fibrosis, tuberculosis, mycoses and dust disease (figure
10.13). Early in the course of the disease films may show granular,
nodular or linear densities. These abnormalities may increase, decrease
or remain unchanged, with or without fibrosis. Upper-lobe involvement
is common. Hilar adenopathy, seen in approximately one-third of
patients, is usually bilateral and accompanied by mottling of the lung
fields. The absence of lung changes in the presence of adenopathy is a
relative but not an absolute differential consideration in favour of
sarcoidosis as opposed to chronic beryllium disease. Unilateral hilar
adenopathy has been reported, but is quite rare.
___________________________________________________________________________
Figure
10.13 Chest roentgenograph of a patient with chronic beryllium
disease, showing diffuse fibronodular infiltrates and prominent hila
__________________________________________________________________________
The x-ray picture does not correlate well with clinical status and
does not reflect particular qualitative or quantitative aspects of the
causal exposure.
Pulmonary function tests
Data from the Beryllium Case Registry show that 3 patterns of
impairment may be found in chronic beryllium disease. Of 41 patients
studied over a period of an average of 23 years after initial beryllium
exposure, 20% had a restrictive defect, 36% had an interstitial defect
(normal lung volumes and air flow rates but reduced diffusing capacity
for carbon monoxide), 39% had an obstructive defect and 5% were normal.
The obstructive pattern, which occurred in both smokers and
non-smokers, was associated with granulomas in the peribronchial
region. This study indicated that the pattern of impairment affects
prognosis. Patients with interstitial defect fared best, with the least
deterioration over a five-year interval. Patients with obstructive and
restrictive defects experienced worsening of their impairment in spite
of corticosteroid therapy.
Studies
of lung function in beryllium extraction workers who were asymptomatic
showed the presence of mild arterial hypoxaemia. This occurred usually
within the first 10 years of exposure. In workers exposed to beryllium
for 20 years or more there was a reduction in the forced vital capacity
(FVC) and the forced expiratory volume in one second (
).
These findings suggest that the initial mild hypoxaemia could be due to
the early alveolitis and that with further exposure and elapse of time
the reduction in 
and FVC could represent fibrosis and granuloma formation.
Other laboratory tests
Non-specific abnormal laboratory tests have been reported in chronic
beryllium disease and include elevated sedimentation rate,
erythrocytosis, increased gammaglobulin levels, hyperuricaemia and
hypercalcaemia.
The
Kveim skin test is negative in beryllium disease, whereas it may be
positive in sarcoidosis. The angiotensin converting enzyme (ACE) level
is usually normal in beryllium disease, but can be increased in 60% or
more of patients with active sarcoidosis.
Diagnosis
Diagnosis of chronic beryllium disease for many years was based on the
criteria developed through the Beryllium Case Registry, which included:
1. a history of significant beryllium exposure
2. evidence of lower respiratory tract disease
3. abnormal chest x ray with interstitial fibronodular disease
4. abnormal lung function tests with decreased carbon monoxide diffusing capacity (DLCO)
5. pathological changes consistent with beryllium exposure in lung or thoracic lymph nodes
6. the presence of beryllium in tissue.
Four
of the six criteria had to be met and should have included either (1)
or (6). Since the 1980s, advances in immunology have made it possible
to make the diagnosis of beryllium disease without requiring tissue
specimens for histological examination or beryllium analysis. The
transformation of lymphocytes in blood in response to beryllium
exposure (as in the lymphocyte transformation test, LTT) or lymphocytes
from bronchoalveolar lavage (BAL) have been proposed by Newman et al.
(1989) as useful diagnostic tools in making the diagnosis of beryllium
disease in exposed subjects. Their data suggest that a positive blood
LTT is indicative of sensitization. However, recent data show that the
blood LTT does not correlate well with pulmonary disease. The BAL
lymphocyte transformation correlates much better with abnormal
pulmonary function and does not correlate well with concurrent
abnormalities in the blood LTT. Thus, to make a diagnosis of beryllium
disease, one needs a combination of clinical, radiological and lung
function abnormalities and a positive LTT in the BAL. A positive blood
LTT by itself is not diagnostic. Microprobe analysis of small tissue
samples for beryllium is another recent innovation which could help in
diagnosis of disease in small lung tissue samples obtained by
transbronchial lung biopsy.
Sarcoidosis is the disorder most
closely resembling chronic beryllium disease, and the differentiation
may be difficult. Thus far, no cystic bone disease or involvement of
the eye or tonsil has appeared in chronic beryllium disease. Similarly,
the Kveim test is negative in beryllium disease. Skin testing to
demonstrate beryllium sensitization is not recommended, in that the
test itself is sensitizing, may possibly trigger systemic reactions in
sensitized people and does not of itself establish that the presenting
disease is necessarily beryllium related.
More sophisticated
immunological approaches in differential diagnosis should allow for
better differentiation from sarcoidosis in the future.
Prognosis
The prognosis of chronic beryllium disease has altered favourably
during the years; it has been suggested that the longer delays in onset
observed among beryllium workers may reflect lower exposure or lower
beryllium body burden, resulting in a milder clinical course. Clinical
evidence is that steroid therapy, if used when measurable disability
first appears, in adequate doses for long enough periods, has improved
the clinical status of many patients, allowing some of them to return
to useful jobs. There is no clear evidence that steroids have cured
chronic beryllium poisoning.
Beryllium and cancer
In animals, experimentally administered beryllium is a carcinogen,
causing osteogenic sarcoma after intravenous injection in rabbits and
lung cancer after inhalation in rats and monkeys. Whether beryllium may
be a human carcinogen is a controversial issue. Some epidemiological
studies have suggested an association, particularly after acute
beryllium disease. This finding has been disputed by others. One can
conclude that beryllium is carcinogenic in animals and there may be a
link between lung cancer and beryllium in humans, particularly in those
with the acute disease.
Safety and Health Measures
Safety and health precautions must cover the fire hazard as well as the much more serious toxicity danger.
Fire prevention
Arrangements must be made to prevent possible sources of ignition, such
as the sparking or arcing of electrical apparatus, friction, and so
forth, in the vicinity of finely divided beryllium powder. Equipment in
which this powder has been present should be emptied and cleaned before
acetylene or electrical welding apparatus is used on it. Oxide-free,
ultrafine beryllium powder that has been prepared in inert gas is
liable to ignite spontaneously on exposure to air.
Suitable
dry powder-not water-should be used to extinguish a beryllium fire.
Full personal protective equipment, including respiratory protective
equipment, should be worn and firefighters should bathe afterwards and
arrange for their clothing to be laundered separately.
Health protection
Beryllium processes must be conducted in a carefully controlled manner
to protect both the worker and the general population. The main risk
takes the form of airborne contamination and the process and plant
should be designed to give rise to as little dust or fume as possible.
Wet processes should be used instead of dry processes, and the
ingredients of beryllium-containing preparations should be unified as
aqueous suspensions instead of as dry powders; whenever possible the
plant should be designed as groups of separate enclosed units. The
permissible concentration of beryllium in the atmosphere is so low that
enclosure must be applied even to wet processes, otherwise escaping
splashes and spills can dry out and the dust can enter the atmosphere.
Operations
from which dust may be evolved should be conducted in areas with
maximum degree of enclosure consistent with the needs of manipulation.
Some operations are performed in glove boxes, but many more are
conducted in enclosures provided with exhaust ventilation similar to
that installed in chemical fume cupboards. Machining operations may be
ventilated by high-velocity, low-volume local exhaust systems or by
hooded enclosures with exhaust ventilation.
To check the
effectiveness of these precautionary measures atmosphere monitoring
should be done in such a manner that the daily average exposure of
workers to respirable beryllium can be calculated. The work area should
be cleaned regularly by means of a proper vacuum cleaner or a wet mop.
Beryllium processes should be segregated from the other operations in
the factory.
Personal protective equipment should be provided
for workers engaged in beryllium processes. Where they are fully
employed in processes involving the manipulation of beryllium compounds
or in processes associated with the extraction of the metal from the
ore, provision should be made for a complete change of clothing so that
the workers do not go home wearing clothing in which they have been
working. Arrangements should be made for the safe laundering of such
working clothes, and protective overalls should be provided even to
laundry workers to ensure that they too are not exposed to risk. These
arrangements should not be left to normal home laundering procedures.
Cases of beryllium poisoning in the families of workers have been
attributed to workers taking contaminated clothing home or wearing them
in the home.
An occupational health standard of 2
, proposed in 1949 by a committee operating under the auspices of the
US Atomic Energy Commission, continues to be widely observed. Existing
interpretations generally permit fluctuations to a “ceiling” of 5
as long as the time-weighted average is not exceeded. Additionally, an
“acceptable maximum peak above the ceiling concentration for an
eight-hour shift” of 25 
for up to 30 min is also permissible. These operational levels are
achievable in current industrial practice, and there is no evidence of
adverse health experience among persons working in an environment thus
controlled. Because of a possible link between beryllium and lung
cancer it has been suggested that the allowable limit be reduced to 1
, but no official action has been taken on this suggestion in the United States.
The
population at risk for developing beryllium disease is that which in
some manner deals with beryllium in its extraction or subsequent use.
However, a few “neighbourhood” cases have been reported from a distance
1 to 2 km from beryllium extraction plants.
Pre-employment and
periodical medical examinations of workers exposed to beryllium and its
compounds are compulsory in a number of countries. Recommended
evaluation includes an annual respiratory questionnaire, a chest x ray
and lung function tests. With advances in immunology, the LTT may also
become a routine evaluation, although at this time not enough data are
available to recommend its use routinely. With evidence of beryllium
disease, it is unwise to allow a worker to be exposed to beryllium
further, even though the workplace meets the threshold criteria for
beryllium concentration in the air.
Treatment
The major step in therapy is avoidance of further exposure to
beryllium. Corticosteroids are the primary mode of therapy in chronic
beryllium disease. Corticosteroids appear to alter the course of
disease favourably but do not “cure” it.
Corticosteroids
should be started on a daily basis with a relatively high dose of
Prednisone of 0.5 to 1 mg per kg or more, and continued until
improvement occurs or no further deterioration in clinical or lung
function tests occurs. Usually this takes 4 to 6 weeks. Slow reduction
of steroids is recommended, and eventually alternate-day therapy may be
possible. Steroid therapy ordinarily becomes a lifelong necessity.
Other
supportive measures such as supplemental oxygen, diuretics, digitalis
and antibiotics (when infection exists) are indicated as the clinical
condition of the patient would dictate. Immunization against influenza
and pneumococcus should also be considered, as with any patient with
chronic respiratory disease.
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