or desiccated thyroid in physiologic dosage

or desiccated thyroid in physiologic dosage

Hydrocortisone and/or Desiccated Thyroid in Physiologic Dosage XII. Effects of Thyroid Hormone Excesses on Urinary Solutes and Steroids C. MOSES Bq ...

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Hydrocortisone and/or Desiccated Thyroid in Physiologic Dosage XII.

Effects of Thyroid Hormone Excesses on Urinary Solutes and Steroids C. MOSES

Bq T. S. DANOWSKI, G. P. RODNAN, M. E. SARVER AND

17-ketosteroids remained constant. The comparable responses to mepyrapone (Metopirone or SU 4885) prior to and during thyroid administration indicate that pituitary-adrenal responsiveness had not been altered by this therapy. The decrease in the urinary 17-ketosteroid and perhaps the compound S responses to exogenous ACTH in our studies indicates that the secretion, conversion, or excretion of these classes of steroids is altered by induced excesses of thyroid The urinary Porter-Silher hormone. chromogen response to exogenous ACTH was not altered. Urinary gonadotropins decreased during treatment with large dosages of thyroid hormone. Total and free hydroxyproline excretion in urine increased during administration of desiccated thyroid in large dosages.

The administration of a preparation of desiccated thyroid in 20 or 25 grain dosages to healthy adult male prisoners was associated with increases in the mean daily urine volume, mean daily creatinine clearance and, sporadically, with an appearance or accentuation of creatinuria. Urine calcium and phosphorus excretion also appeared to increase but the changes were not statistically significant. The origins of the trends to hypercalciuria and hyperphosphaturia cannot be identified because balance data are lacking, but presumably variables such as the increased intake of food and the loss of skeletal calcium and phosphorus which characterize thyrotoxicosis were operative. The tubular reabsorption of filtered phosphorus remained constant. The daily excretion of urinary PorterSilber chromogens increased, while the MONG

A

OTHER

human

mav develop

AND URINARY glomerular

if already

rate

in thyrotoxicosis

increases,lR*”

present,sa-i the urinary the metabolism

excretion and

steroids is often alteredJa-V and the output

increases.5a, 1’ Onr findings

thyroid

(Proloid)

keeping

with these findings,

in large

dosages

during

ing that the urinary

steroid

(Metopirone

responses

of Endocrinology

the

for a limited

In addition,

venous mepyrapone ._ _______ From. the Section

CH,4NGES

filtration

rises,.?“-” the secretion,

of adrenal

in lirinr

the

or increase

and phosphorrls cretion

RENAL

subjects

in

creatinuria of calcium

the urinary

ex-

of hydroxyproline

administration

of desiccated

period

are largely

evidence

of time

has been

to exogenous

ACTH

obtained but

cr SU 4885)

may be altered

and Metabolism

and the Section

in

indicat-

not to intraby these

large

of Rheumatology

of the Departmcvlt of Medicine. the Addkon H. Gibson Laboratory, Unicersity of Pittsburgh, c11lt1tht, ,\letlicul Center und Shadyside Hospitah, Pittsburgh, Penn&xmia. Aided by grunts from the John A. Hartford Foundation, Inc., the Western Pennsyhati Chapter of tllc iL\rtlwitisand Rheumatism Foundation, the Muscular Dystrophy Assocbtions of dmericw Inc., the Medical Research Fourukrtion of Pennsylcania, Inc., tk ~~,nl~r,o,lccrclltlt of Pewwylcunk. the Deportment of ffenlth. Education nnd Welfare. unc( U,‘clrfler-Larr!bert L&oratories. Rwcirwl

for 7~uOlication Feb.

14. 7964.

h[ETABOLISM,

\'OL. 13, NO. 8 (AUGUST),

1964

730

DANOWSKI,

Table I.-Efects

of Large

Dosages of Desiccated Thyroid Creatinine, and Creatinine Clearance ~~__

__-______ Week of

Urine Volume (ml/d.)

Dosage

Therapy

(grains)

0

0

0 0 7th

RODNAN,

Mean

& S.D.

830 *

SARVER AND MOSES

on Urine Volume,

Urine Creatinine (mg./d.) Mean i S.D.

(#)

Creatinine Clearance (ml./min.) Mean 2 S.D.

(#)

(#)

241

(8)

1460 2 445.1

(3)

0

1008 2 311

(8)

1513 % 423.7

(8)

106.3 I

32.07

0

1107 ZL 720

(7)

1285 *

357.7

(7)

32.3 ?

19.68

(7)

20t

1245 & 763

(10)

1027 t

489.0

(10)

80.7 ?

52.37

(10)

127.4 f

62.15

91.7 5 28.97

(8) (8)

9th

25

1511 r!~ 528***

(10)

1363 *

464.5

(5)

10th

25

1680 % 752***

(10)

1440 2 625.0

(10)

11th

25

1455 f

470***

(8)

1596 -t 365.2

(5)

151.x 2 52.37*

(5)

13th

0

1267 2

382*

(6)

1691 ?

221.4

(6)

152.1 i

31.31***

(6)

14th

0

1448 ?I 423’**

(6)

1851 *

426.6

(5)

126.2 i

38.11

(5)

15th

0

1232 % 319**

(6)

1512 t

408.5

(6)

105.3 ?

28.57

17th

0

llfiO?

(6)

Difference

from

pretherapy

546’ values

~___.

statistically

significant:

*p

by 2 weeks

therapy

for

period

dosages such

each

2 weeks

(weeks

I3

of thyroid

a regimen

on grains

3,

(weeks

7 and

through

17).

hormones

urinary

10 and

8):

25 per

administered

gonadotropins MATERIALS

Twenty-four

15 per

grains

hour specimens

of urine

(6)

__..

..-.

.02-.Ol.

***p tpreeeded

_~_

(10)

.O5&.02.

**p

was continued

(5)

117.4 I75.01

.Ol-<.OOl.

day

(weeks

day

for

1 through

4 weeks

for brief

6);

(weeks

periods,

grains

20 per

day

9 through

12):

Post-

and that

under

may decrease. AND

METHODS

were collected

with refrigeration

prior

to, during

and after the administration of desiccated thyroid (Proloid: Lots 2827072A, 156905A and 459312) in daily dosages increasing up to 25 grains. The volumes of the specimens were measured

and aliquots were analyzed or assayed for creatinine, creatine, calcium, phos17-ketosteroids, Porter-Silber chromogens, 11-desoxycortisol ( compound S) phorus, metaholites, pressor activity, gonadotropins and hydrosyproline by methods in use in this and in other laboratories. err Also, the effects of such excesses of thyroid hormone on the urinary

steroid

intravenous

responses

to subcutaneous

mepyrapone,

ACTH,

200

units

36 mg. per Kg. of body weight,

per day for 4 days,

were

and to

examined.

RESULTS

Urine Volz~me, Creatinine The

%&hour

desiccated

also increased (table

1).

urine

thyroid

Creatinuria

urinary

present

neither effect

clearly

during

upon urinary

with

not

associated

with

therapy

during 1).

The

the daily

ingestion

creatinine

of

clearance

desiccated

did not increase. equal

but it was almost

the treatment period ( SU 4885 ) nor ACTH creatine

with

of creatinine

approximately

frequency always

prior

to

and

more pronounced

(table 2). It is to be noted that administration had anv consistent

excretion.

Uritbe Calcium and Phosphorus; ‘- Treatment

(table

to 151.7 from a base line level of 91.7 ml. per minute

thyroid

mepyrapcne

increased

dosage

excretion

occurred

duringdesiccated when

volumes

in 25 grain

strikingly

The

and Creatine

Tubular

thyroid

statistically

Reabsorption

of Phosphorus

in 20 to 25 grain per day dosages significant changes in urine calcium

was and

though a trend to increases was recorded (table 3). phosphorus excretion, None of these differences was statistically significant. Since the intake of

THYROID

HORhIONE

ON

URINARY

Pretherapy Week2

C. Ba. w.

B.

0

0

12

68

731

STEROIDS

Prior to, during,

25 grains/d.*

~_____ Week

Week1

2

Week

3

Post-Therapy

SU-4885t

213

32

311

0

0

45

I,

C. Br. G. c.

AND

of Creatine in Urine (mg./d) and after Thyroid Therapy ~ .-.___

Table 2.-Excretion

Subject

SOLUTES

Week1

ACTHZ 36

6

0

40

90

0

50

Week2 ~.__

Week

0

0

43

0

16

0

107 0

56 12

88 125

0 0

0

0

43

0

0

J. M.

0

16

0

0

44

86

8

0

Y

Ii. s.

0

18

0

0

0

0

0

0

R. H. K. Mc.

*During

2nd

and

3rd

I)

weeks

then

3 __

0

of

25

20 per

grains

day

for

of

thyroid

grains

3, 10,

15 and

tall

values

in

this

column

obtained

on

2 weeks day

iAll

values

in

this

column

obtained

on

fourth

per

day

immediately

by,

preceded

in

0 succession.

each.

of

intravenous day

of

SU-4885

ACTH

test.

stimulation

test.

‘I‘able 3.-Urinary Calcium and Phosphorus Excretion and Tubular Reabsorption of Phosphorus Prior to, during and after Desiccated Thyroid Therapy in Large Dosages Urine Week of Therapy

Dosage (grains)

_~~_

Tubular Reabsorption of Phosphorus (‘A.) Mean 5 S.D. (#)

0

176 i

98

(8)

774 t

203

(9)

84.1 f

3.0

18)

0

I,

164 1+ 75

(i)

144 t- 265

(9)

88.0 f

3.3t

(8)

fi74 -c 91

I)

7th

20*

104

17)

194 & 148

182 ?

(IO)

(R)

83.4 5

3.2

(7)

683 2

395

110)

81.2 2

8.0

(10)

9th

“5

261 I+ 112

(19)

885 ‘-

333

110)

86.8 t- 4.9

(5)

10th

25

272 ?

203

(10)

801 & 325

(9)

84.7 % 4.3

(10)

1lth

“5

212 -+r 202

(i)

912 t

432

(8)

82.6 2

5.6

(3)

13th

0

155 ?

63

(6)

947 2

310

(6)

90.2 ?

2.6t

(5)

14th

0

231 i

169

(6)

860 f

497

(6)

X6.9 2

3.1

(5)

15th

0

215 t- 68

(5)

975 t- 181

(6)

82.5 i- 5.2

(6)

17th

0

141 *

(5)

655 ?z 202

(6)

*Preceded

by

continued

therapy

2 weeks for

period

tDiffewnce

these

(weeks

The

during

tubular

25 per

day

(weeks

day

for

1 through

4 weeks

6);

(weeks

grains

20 per

9 through

121;

day post-

is statistically

significant

intake,

p .05&.02.

it is not possible

endogenous

release,

etc.

to assess the rela-

in the trends

to hvper-

reabsorption

urinary

of filtered

of desiccated Porter-Silber excretion

of

phosphate thyroid

(per

in large

Chrom.ogrrzs 17-ketosteroids

and

cent

TRP)

dosages Compound

remained

was

(table

not

3 ).

S

quite

constant

the ingestion

of 20 to 25 grains of desiccated thyroid (table 4). On as much as twofold increases in Porter-Silber chromogens

hand, during

urinary

not change

the same period. excretion

consistently

Stcroi&

Thcrapv adrenal

15 per

grains

could not be estimated,

I;-Kctosteroids, meau

other

Urirwrrl

8);

17).

value

hv the ingestion

occurred The

3, 10 and

7 and

_.__~.

and hyperphosphaturia.

ZTriwrrl The

54

grains

13 through

of dietary

calciuria

on

(weeks

pretherapy

constituents

altered

each

2 weeks

from

tive roles

the

___

Phosphorus (mg./d.) Mean -t S.D. (#)

0 0

was

Calcium (mg./d.) Mean -+: S.D. (#)

with

of compound (table

S ( 11-desoxycortisol)

follotcjing SU 4885 (hletopirone) desiccated

responsiveness,

metabolites

did

4).

thyroid

judging

from

did

not

or Exo,oenow enhance

the results

nor

ACTH

reduce

of intravenous

pituitary

mepyrapone

739

DAiYOWSKI,

Table

RODNAN,

SARVER

AND

MOSES

4.-Eflects of Large Dosages of Desiccated Thyroid on the Urinary Excretion (mg./d.) of l?-Ketosteroids, Porter-Silber Chromogens, and 11-Desoxycortisol (Compound S) Metabolites Dosage (grains)

Week of Therapy

17-Ketosteroids Mean k S.D. (#)

Porter-Silber Chromogens Mean k S.D. (#)

Compound Mean k S.D.

S (#)

II

0

10.7 e

4.3

(8)

4.8 k 2.2

(8)

0.37 5 0.2

(8)

0

0

11.8 4

3.6

(8)

5.2 r+ 1.9

(8)

0.34 f

0.2

(8)

0



6.4 f

(7)

0.48 +- 0.3

(1)

0

10.3 t 3.2 10.1 2 3.2

(7)

0

(10)

0.29 k 0.4

(10)

0.64 t

(7)

7th

20

9.4 rtr 5.2

(19)

9th

26

10.5 k 3.5

(10)

10th

25

10.2 t

(10)

11th

25

10.0 -c 3.4

(8)

14th

0

12.6 f

3.3

(6)

15th

0

11.2 i

3.3

(6)

9.2 k 3.9 --___~__~

(6)

0

17th ______~ *p < 0.01.

6.9

2.7

6.6 zk 5.4 10.6 2

3.6*

0.4

(9) (10)

Table 5.-Comparable

Urinary 17-Ketosteroid, Porter-Silber Chromogen, 11-Desoxycortisol (Compound S Metabolites) Responses to lntravenous Mepyrapone Prior to and during Large Dosage Thyroid Therapy ~--_ .____ 17-Ketosteroids (mg./d.) MeaIl (#I ______

Porter-Silber Chromogens (mg./d.) MeaIl (#)

and

Compound S (mg./d.) Meall (#)

Before Thyroid Therapy Pre-SU

4885

Day of SU 4885

11.4

(7) (7)

5.5 14.7

(6) (7)

0.5

15.8

4.6

(6) (7)

11.3 14.8 11.5

(7) (7) (7)

9.8 15.1 10.8

(7) (7) (7)

0.6 5.7 1.0

(7) (7) (7)

During Thyroid Therapy” Pre-SU

4885

Day of SU 4885 Day after SU 4885

____ ‘During

the fourth week of treatment

grains 3, 10, 15 and 20 per day during dosages.

with 25 grains per day preceded successive

periods

of 2 weeks

by therapy on each

with

of these

tests (11-desoxycortisol metabolites and Porter-Silber chromogens as indices) in the 7 subjects tested before and during the administration of this hormone (table 5). The slight 17-ketosteroid change is in keeping with one of the patterns seen during intravenous mepyrapone tests and has no significance as an index of pituitary-adrenal responsiveness. The responses to exogenous ACTH may have been changed by desiccated thyroid therapy. During the treatment period exogenous ACTH produced comparable increases in urinary Porter-Silber chromogens but the 17-ketosteroid and ll-desoxycortisol metabolite responses were less (table 6). It should be pointed out, however, that the comparisons in table 6 are based on control studies conducted in another group of prisoners and may not be valid. Urinary

Gonadotropin

and

Hydroxyproline

Excretion

Gonadotropin excretion in urine decreased during thyroid feeding (fig. 1). Urinary hydroxyproline levels (total and free) increased during thyroid administration in all of the men on whom observations are available (table 7).

Table 6.-Decrease during Large Dosage Thyroid Therapy in the Usual Urinary 17-Ketosteroid Response (mg./d.) to Exogenous ACTH (200 units S.C. per day for 4 days) Pwter-Silber (mean

17-Ketosteroids (mean (f) ) AC’TH

Thyroid

NolIe

:j days

4 days

Non.2

3 days

4 days

.57.:!

52.1

7.4

32.6

27.1

0.4

4.4

4.4

1X0)

(2!J)

(29,

(45)

(X)

(17)

(6)

(4)

(4)

11.2

1X.B

25.0

9.8

33.1

:i.i.4

0.6

1.9

1.x

(7)

(7)

(71

(7)

(7)

17)

(7)

(7)

(7)

3 days

Its+

grou,~

“Prisoners

other

iDuring 3. 10,

4 days

12.3

NOIF2

nx

i’,,ntr<,ls”

than

fourth

15 and

The

20

those

week per

of

day

increase

dosages

participating

25 for

grains

of

2 weeks

in the

of desiccated

daily

intake

that such increased

of water,

The

solute

increase

dosages

load,

filtration

and

other

most attractive and decrease tration.

renal

data

in

succession.

from

therapy

by

during

mains

points

Also,

one ma) of water

as a result

administration

levels,

amine activity

that

variables

clearance,

of large

of glomerular

hyperthyroidism.lH,ll

is the increase which

the observed

demonstrable

glomerular

in blood

clinical

of

is lacking.

is in line with the enhancement during

large by an

losses

or in urine the

with

accompanied

increased

on these

clearances

albumin

a role by altering

during

are not available.

for this change

pressor

ceding

of urine

of hypermetaholism

It may well he, however,

role in the decrease

preceded,

1) was presumably stemmed

function

explanation

of the rise in creatinine

study.

immediately

hut informaticn

medullary

in plasma favor

increase

The volume

glomerular in the

fil-

adreno-

in the urine of these suhpectsTa

filtration.

irrespective

such increases

NPN and serum

may have

of the origins in turn played

uric acid described

a

in the pre-

report.‘”

The increased creatine

urinary

observed

of pre-existent

of animals

ale.“;‘-” One might evident

it is possible

there

reason

ness and myopathy

during

rise. in the plasma

creatinuria

in part the rises in serum with

can develop

observed to store in clinical

hand grip strength creatine

hormone

in growing

and urinarv

was

excretion

creatinuria

children

that in experimental creatine

phosphate to the muscle

thyrotosicosis@

in our studie+

phosphokinase

excesses

the

males and the aggravation

that this is in some way related

the lowered levels

reflects

et al. suggest

is an inability

which

thyroid

2)

thyrotoxic

of Dinning

as decreased

that

(tzhle

patients.- I” It is in keeping

in spontaneously

in women.2n-i The studies toxicosis

creatine

in these

may develop

thyrotoxicosis

subjects

thirst

thyroid

in plasma

therapy

day

hut intake

also plays

became

(table

in creatinine

of desiccated

per

volumes

skin as a consequence

an increased

thyroid

Proloid

thyroid

increased through

in

each.

speculate

which

11-Desosyeortisol Metabolites (mean (#) )

Chromogens (#) )

activity

in part of creatine.

by and

thyroin musx\reak-

and which Alternatively, noted

responsible

in our for

the

734

DANOWSKI,

0-4

CBDBWB-

l emo

0000

l eoo

0.40 0000 0000 0000 ..+o 0 00 0000

l

RI-IRM-

oooo l ooo

KMJM-

l eoeoo

l..+

000 l @*@O

JMi-

0000 0000

l

0000

0000

OeOO

OSDTm

‘.OOO

0.04

GWKTCBr-

0.00 0000

0000 0000

moo0 0000

0000

0004 0.40 0000

-44 0000

000 0.00 0.00 0000

0000

0000

0000

0.00

0.00

0000 0000 0000

0000 0.0.

P20

P25

lO/l7-18

lo/w-17

0000

0000

0000

. ..*+ ..o..O ..q

0000 0000

0000

0000

m.@

0000 0000 0000

0.40

RS- soeooo 0.4. RSc-

a.04 0.00 0000 0000 0000

..+0

0.00 oo l oooee

WPSBGC-

SARVER AND MOSES

0000 0000 0.00 0000 0000

4.40

DBi- 0000

RODNAN,

11127

12112

.3/b-7

0000

0000

00.0

0000

P25

P25

3113-14 3120-21

3127-28

Fig. l.- Decrease in urinary gonadotropins during therapy with desiccated thyroid in large dosages. The frequency of positive assays for urinary gonadotropins and the amount of gonadotropins present decreased during ingestion of Proloid in increasing dosages. Solid circles indicate uterine and ovarian hyperemia and weight increase in both mice at the particular dilution of urine protein indicated, i.e., 1:3.3, 6.6, 13, etc. Open circles with vertical bar indicates that a positive response was obtained in only 1 of the 2 mice at the dilution indicated. Open circles indicate no response in both mice.

Urine Calcium and Phosphorus; The during (table lacking.

origins the 3)

of the

ingestion cannot

Published

trend

Tubular Reabsorption

to increases

of thyroid

be identified balance

in urine

hormones because

data

are

calcium

in excess

as already compatible

of Phosphorus

indicated with

and

phosphorus

of replacement intake

an increased

needs data

are

calcium

THYROID

HORMONE

ON

URINARY

Table 7.-Urinary Administration

SOLUTES

735

STEROIDS

Hydroxyproline Excretion of Desiccated Thyroid OH-Proline

Before

AND

Prior to and during

the

in Large Dosages

(mg./d.) During

Rx

Rx*

Creatinine

Total

Fvee

Total

Frcr

18.8 22.5 38.3

0.8 0.X 1.*5

77.4 93.8 36.3

2.4 2.1 0.8

.96 1.27 1.83

1.30 1.28 ,92

18.”

1.1

80.7 117.2

1.7 2.5

1.06

1.03 1.39

IL ;\I. J. XI. R. S. C. Br.

‘IIllring trwtmcnt with 25 grains of desiccated 8 weeks of continuous thyroid therapy, i.e.. grains day for 2 weeks each.

thyroid. 3, and

Rx

During

Subject c.

Ba.

Before

(a./cl.)

This tlosagt> was prrcetld then IO, 15 and 20 grains

Rx-i

1,~. pm

and phosphcrus loss from exogenous and endogenous sources. increased fecal representing largely skeletal and urinary excretion, and negative balance, losses, of these two elements. The constancy of the tubular reabsorption of phosphorus suggests that parathyroid activity and effects were not altered ‘by the large dosages of thvroid. C7rincmy 17-Kctosteroitls, Jlctaho1itc.s

Pffrter-Silber

Chromogens

anrf

11 -De.roxrpr-tisol

It has been concluded on the basis of hydrocortisone degradation estimates that in clinical thyrotoxicosis there is an increased demand for this steroid. This is almost always met by an adequate increase in the secretion of hydrocortisone, though occasionally adrenocortical insuf&iencv and a crisis ma\’ resu1t.l’~~ Our data are consonant with this hvpothesis in that the urinarv (Yi cretion of Porter-Silber chromogens increased twofold during thyroid ‘therap\’ ( table 3 ). ~lrinnrrl Steroids

after

Mep~yqmne

or ACTH

Injection

The constancy of the 11-desoxycortisol metabolite and Porter-Silber chromogen responses to intravenous mepyrapone (table 5) prior to and during thvroid administration establishes that pituitary-adren:ll function was not aliercd by excesses of those hormones. Our data, which show only the usual increase in urinarv Porter-Silher chromogen excretion after exogenous ACTH (table 6), are not in keeping with the general hypothesis that adrenocortical activity may be increased in clinical thvrotoxicosis. It could be that the absence of such increases in ollr stlldies are attributable to the exog;enous source of the thyroid excess or to c the short period of treatment and the relatively small dosages of thyroid used. The decreased urinary 17-ketosteroid excretion after exogenous ACTS in our treated sllbjects (table 6) suggests that steroidogenesis or metabolic and txretorv processes productive of urinarv 17-ketosteroids are altered b\, illt111ced clxcesses of thvroid hormones,

736

DANOWSKI,

Urinary Gonudotropins The

decrease

diminished available The

rise in total

with findings of collagen

levels

of urinary

secretion

on the libido

SARVER

AND MOSES

and Hydroxyproline

in the

pituitary

RODNAN,

or sexual

and free

activity

urinary

in spontaneous

gonadotropins

or increased

during

from connective

tissues

thyroid

hydroxyproline

thyrotoxicosis5B~b

(fig.

metabolism.

1)

No

may

reflect

information

is

feeding.

(table

7)

and presumably

is in keeping reflects

release

and bone.

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of

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