Changes of Peripheral T Lymphocyte Subsets Following Treatment in Patients with Bronchogenic Carcinoma

Ju-Ock Kim; Sun-Young Kim

doi:10.3904/kjim.1989.4.2.101

Korean J Intern Med > Volume 4(2); 1989 > Article

Kim and Kim: Changes of Peripheral T Lymphocyte Subsets Following Treatment in Patients with Bronchogenic Carcinoma

Original Article

The Korean Journal of Internal Medicine 1989;4(2):101-107.

DOI: https://doi.org/10.3904/kjim.1989.4.2.101

Changes of Peripheral T Lymphocyte Subsets Following Treatment in Patients with Bronchogenic Carcinoma

Ju-Ock Kim, M.D., Sun-Young Kim, M.D.

Department of Internal Medicine, College of Medicine, Chungnam National University, Daejeon, Korea

Address reprint request: Ju-Ock Kim, M.D., Department of Internal Medicine, College of Medicine, Chungnam National University, #640 Daesa-dong, Jung-ku, Daejeon, 301-040, Korea

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/3.0/) which permits unrestricted noncommercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

We evaluated the changes of peripheral leukocyte counts, lymphocyte counts, and percentage of lymphocytes and T cell subsets (OKT4(%), OKT8(%) and OKT4/OKT8) in 49 untreated lung cancer patients of whom 23 were followed up after therapy (8 pulmonary resection, 15 chemotherapy). Total WBC counts were significantly increased in stage I or II compared to controls and were decreased after operation.

Total counts and percentage of lymphocytes were decreased (esp. stage III NSCLC, SCLC esp. ED, squamous) and were persistently decreased after treatment in nonresponders. OKT8(%) was decreased (esp. SCLC, squamous, adenocarcinoma, all stages of NSCLC, and ED of SCLC) and was persistently decreased in stage III after treatment.

The OKT4/OKT8 ratio was increased (esp. adenocarcinoma and stage III NSCLC) and returned to the normal range after treatment.

In nonresponders, total lymphocyte counts were decreased before treatment compared to responders and persistently decreased before and after treatment compared to controls, and OKT8(%) was persistently decreased after treatment compared to controls.

In conclusion, immunoabnormalities in patients with lung cancer might be improved following treatment.

Keywords: T lymphocyte subsets; OKT4; OKT8

INTRODUCTION

Patients with lung cancer often display impaired immunity,^1–10) including low counts of T-lymphocytes, and these impairments have been postulated to be significant in the development and progression of lung cancer, and the nutritional status of patients has been contributed to immunologic abnormalities⁴⁾.

Recently, Wesselius et al.⁴⁾ have reported on lymphocyte subsets in patients with untreated lung cancer, and we also have reported on T lymphocyte subsets in patients with untreated lung cancer.¹⁰⁾ But most studies, including our previous study¹⁰⁾, have evaluated only untreated cases.

In the present study, we undertook to further evaluate the changes of peripheral T lymphocyte subsets in patients with lung cancer following treatment (anticancer chemotherapy and pulmonary resection).

MATERIALS AND METHODS

1. Patients

Forty-nine untreated patients (41 men and 8 women) with primary lung cancer (ages; 38 to 75 years; mean, 57±10 years; 24 squamous, 10 adenocarcinoma, 11 small cell, 4 undifferentiate carcinoma) (Table 1) and 28 normal subjects (23 men 5 women; ages, 45 to 65 years; mean, 55 ± 14 years) were studied.

Patients with non-small cell lung cancer (NSCLC) were 38 in number and were staged by the TNM classification. Clinical staging indicated that 9 were stage I or II and 29 were stage III. In the 11 patients with untreated small cell lung cancer(SCLC), 3 were classified as having limited disease(LD) and 8 had extensive disease(ED).

Among 49 patients with untreated lung cancer, 23 had received treatment, of whom 15 had received anticancer chemotherapy alone (3 SCLC, 1 stage I or II, 11 stage III) and 8 had received pulmonary resection alone (stage I or II). Patients who received pulmonary resection or chemotherapy had blood samples taken 2 to 4 weeks after operation and 3 months later after chemotherapy (Cytoxan-Adriamycin-Etoposide or Cisplatin-Etoposide regimen every 3 weeks), respectively.

The assessment of response to anticancer chemotherapy was identical with that described previously¹⁷⁾ and postoperative patients were considered to be responders.

2. Evaluation of Peripheral Lymphocytes

The total WBC, lymphocyte counts and percentage of lymphocytes were determined by a Coulter Counter Model S-Plus. The monoclonal antibodies were obtained from Ortho Pharmaceutical Corporation (Raritan, New Jersey, USA). The antibodies used in this study included antibodies OKT4 (helper/inducer) and OKT8 (suppressor/cytotoxic) T-cells.

Peripheral blood mononuclear cells were isolated by Ficoll-Hypaque gradient centrifugation of heparinized blood, were incubated for 30 min. with the monoclonal antibodies and then labelled with a fluorescein-conjugated goat antimouse serum (GAM-FITC, TogoLab, Netherland). Fluorescein cells were counted by means of indirect fluorescent microscope (counted 200 cells), and were expressed as percentage.

3. Statistical Evaluation

Student two-tailed unpaired t test was used to compare mean values of normal controls and of patients, and paired t test was used to compare mean values following treatment (before vs. after treatment).

All results were expressed as mean ± SD.

RESULTS

1) Total WBC counts, lymphocyte counts and percentage of lymphocytes in patients with untreated lung cancer (Table 2)

Total lymphocyte counts and percentage of lymphocytes in patients with lung cancer were decreased significantly compared to normal controls (p<0.02).

Total WBC counts were increased in patients with stage I or II, but total lymphocyte counts in stage III and ED of SCLC, and the percentage of lymphocytes in ED were significantly decreased (p<0.005).

Total WBC counts were increased in squamous cell cancer (p<0.05), and lymphocyte counts were decreased in squamous cell, small cell and undiffrentiated cancer, but there was no significant difference between patients with adenocarcinoma and normal controls. The percentage of lymphocytes was significantly decreased in patients with squamous cell cancer and small cell cancer (esp. ED).

2) Changes of total WBC counts, lymphocyte counts and percentage of lymphocytes after treatment (Table 3)

Twenty-three patients with lung cancer had received pulmonary resection (n = 8) or anticancer chemotherapy (n = 15). There were no significant differences in the total counts and percentage of lymphocytes, but total WBC counts were significantly decreased after operation compared with before operation (p = 0.02).

3) T-cell subsets in patients with untreated lung cancer (Table 4)

There was no significant difference between patients with lung cancer and normal controls in OKT4(%). Patients with lung cancer, however, had significantly decreased OKT8(%) (p<0.01).

Patients with undifferentiated carcinoma had significantly decreased OKT4(%) (p<0.05), patients with squamous cell cancer, adenocarcinoma and SCLC had significantly decreased OKT8(%) (p<0.05) and the OKT4/OKT8 ratio was significantly increased in patients with adenocarcinoma. There was no significant difference between any stage of lung cancer and normal controls in OKT4(%), but OKT8(%) was significantly decreased in patients with all stages of NSCLC and ED of SCLC (p<0.02).

There were no significant differences between patients with stage I or II NSCLC and SCLC in OKT4/OKT8 ratio, but patients with stage III NSCLC had a significantly increased OKT4/OKT8 ratio (p<0.02).

4) Changes of T cell subsets following treatment (Table 5)

The 23 patients with lung cancer also had significantly increased OKT4/OKT8 ratios (p = 0.02), and this was increased in stage III NSCLC before treatment compared to normal controls. OKT8(%) was also significantly decreased in untreated patients and in all stages of NSCLC compared to normal controls.

There were no significant differences before and after treatment in OKT4(%) and OKT8(%), but OKT8(%) was persistently decreased after treatment compared to normal controls. The OKT4/OKT8 ratio was significantly decreased after treatment compared to before treatment, and was more apparent in patients with stage III NSCLC, which showed no difference between after treatment and normal controls, suggesting improved immunoregulatory functions.

5) Comparison of total WBC counts, lymphocyte counts, percentage of lymphocytes and T cell subsets following treatment according to mode of response (Table 6)

Total WBC counts of patients with lung cancer were significantly increased in responders before treatment (p<0.02) compared to normal controls, and total counts of lymphocytes were significantly increased in responders (p<0.03) compared to nonreponders before treatment. Total counts and percentage of lymphocytes before treatment were significantly decreased in nonresponders compared to normal controls and were persistently decreased after treatment (p<0.02).

There were no differences between responders, nonresponders, before and after treatment, or normal controls in OKT4(%). Patients with lung cancer had decreased OKT8(%) in responders and nonresponders before treatment compared to normal controls and had persistently decreased OKT8(%) in nonresponders after treatment.

There were no significant differences between normal controls, before and after treatment, responders or nonresponders in the OKT4/OKT8 ratio.

DISCUSSION

There are many reports that patients with lung cancer often display immune abnormalities,^{1–10,13,14,18)} and these abnormalities in cell mediated immunity have been considered to be significant in the development and progression of lung cancer^{1,4,9,15,16,20,21,23)}.

Evaluation of immunocompetence in patients with lung cancer by peripheral total lymphocyte counts,^1,4,8–10) percentage of lymohocytes,³⁾ delayed skin hypersensitivity test,^{6,10,20,21,23)} quantitation of peripheral lymphocyte subsets^{4,5,7,9,10,12)} and mitogen stimulation of lymphocytes^2,8) has demonstrated both functional and quantitative abnormalities.

However, conflicting data have been reported on the distribution of mononuclear cell populations in patients with lung cancer^{3–10,11,16,19,22)}.

In the present study, we evaluated the distribution of peripheral T lymphocyte subsets in patients with untreated lung cancer and changes of T lymphocyte subsets following treatment (pulmonary resection or chemotherapy).

The present investigation revealed that patients with untreated lung cancer had increased total WBC counts in stage I or II NSCLC (esp. squamous cell cancer) compared to normal controls, which were significantly decreased after operation and were also noted in responders. Olkowski et al.³⁾ and Dellon et al.¹⁶⁾ found that patients with lung cancer had increased WBC counts, especially in adenocarcinoma, but our study revealed this in squamous cell cancer and we considered that it may be due to distal bronchial obstruction causing inflammation or a pneumonic process.

Patients with untreated lung cancer had significantly decreased percentages and absolute counts of peripheral lymphocytes compared to normal controls, which were more apparent in stage III NSCLC, SCLC (esp. ED) and squamous cell type, but these abnormalities were not changed or improved after treatment.

The nonresponder group had a significant decrease in lymphocyte counts compared to responders before treatment, and had a decrease in percentage and absolute counts of lymphocytes compared to normal controls before and after treatment. We suggest that patients with initial (untreated) lower lymphocyte counts may be possible nonresponders following treatment.

We found that patients with advanced lung cancer had decreased lymphocyte counts, and this finding is in accord with other results^{1,3,4,7,8,10)}.

Roberts et al.¹⁾ reported that lymphopenia was a feature of patients with metastatic disease of bronchial carcinoma. Krant et al.⁶⁾ found that circulating lymphocytes were decreased significantly during the months approaching death.

Patients with untreated lung cancer had a significant decrease in OKT8(%) compared to normal controls, and this was decreased in patients with SCLC (esp. ED) and all stages of NSCLC (esp. squamous and adenocarcinoma).

These results are in discord with other results,^4,5,7,12) but we confirmed our previous study.¹⁰⁾ Ginns et al.²³⁾ reported that patients with squamous cell cancer involving lymph nodes (N1 or N2 disease) had a decrease in numbers and percentage of T8 lymphocytes. Because our treated NSCLC cases consisted mainly of squamous cell cancer, decreased OKT8(%) is considered to be consistent with Ginns et al.²³⁾ Gross et al.⁸⁾ found that a decrease in circulating rosette-forming cells was predictive of carcinoma in undiagnosed pulmonary coin lesion. However, Jansen et al.¹³⁾ and Lichtenstein et al.¹⁴⁾ have reported that there were no abnormalities of circulating T cells in patients with lung cancer. Recently, Wesselius et al.⁴⁾ reported that patients with SCLC and advanced NSCLC had a significant decrease in the number of T4 and T8 cells.

In any case, regardless of whether or not T cell subsets had changed, we consider that these changes would be due to methodologic differences⁵⁾, compartmentalization into lungs¹¹⁾ or clonal expansion.

Patients with untreated lung cancer had a significant increase in the OKT4/OKT8 ratio compared to normal controls, which was noted in adenocarcinoma and stage II NSCLC, and was considered to be due to the decrease in OKT8(%).

The significance of this finding is open to speculation, but this result is the same as those of other studies.^5,10)

After treatment, the decreased OKT8(%) before treatment returned to the normal range in patients with stage I or II NSCLC, but remained persistently decreased in stage III and nonresponders. So, we suggest that patients with advanced lung cancer having low lymphocyte counts before treatment and decreased OKT8(%) after therapy might not be responsive to treatment.

The increased OKT4/OKT8 ratio in stage III NSCLC returned to the normal range, and this finding suggests that immunoabnormalities in patients with lung cancer might be improved following treatment with or without response.

In summary, patients with lung cancer had immunologic abnormalities, such as decreased lymphocyte counts, decreased OKT8(%) and increased OKT4/OKT8 ratios, and these abnormalities might be improved following treatment.

Further data monitoring the quantitative and functional changes (esp. for SCLC) of lymphocytes following treatment (including radiotherapy) are needed to analyse the role of immunologic changes for the progression, recurrence and prognosis of lung cancer.

Table 1.

Patients Characteristics According to Histology and Stage (n = 49)

		Untreated (n = 26)	Treated (followed-up, n = 23)
Histology
Squamous (n = 24)		9	15
Adenocarcinoma (n = 10)		6	4
Small cell cancer (n = 11)		8	3
Undifferentiated (n = 4)		3	1
Stage
NSCLC^*	Stage I or II (n = 9)	3	6
NSCLC^*	Stage III (n = 29)	15	14
SCLC^**	Limited (N = 3)	2	1
SCLC^**	Extensive (n = 8)	6	2

^* Non-small cell lung cancer

^** Small cell lung cancer

Table 2.

Total WBC Counts, Lymphocyte Counts and Percent of Lymphocytes in Normal Controls and Patients with Lung Cancer (n = 49)

	WBC Counts (/mm³)	Lymphocytes (/mm³)	Percent (%)
Normal controls (n = 28)	7345 ± 1606	2675 ± 456	37.4 ± 7.3
Patients (n = 49)	8224 ± 4030	2113 ± 878^*	29.7 ± 16.2^*
	Stage
NSCLC (n = 38)
Stage I or II (n = 9)	9822 ± 3547^**	2890 ± 899	31.5 ± 10.8
Stage III (n = 29)	8310 ± 4474	2027 ± 732^**	31.0 ± 18.8
SCLC (n = 11)
Limited (n = 3)	7500 ± 2042	2393 ± 1069	32.0 ± 10.5
Extensive (n = 8)	6362 ± 2979	1451 ± 780^**	22.8 ± 13.4^**
	Histology
Squamous (n = 24)	9795 ± 4718^***	2175 ± 812^***	27.5 ± 16.0^***
Adenocarcinoma (n = 10)	6960 ± 2620	2398 ± 1030	36.4 ± 16.8
Small cell cancer (n = 11)	6672 ± 2707	1708 ± 921^***	25.3 ± 12.8^***
Undifferentiated (n = 4)	6225 ± 2523	2140 ± 688^***	39.7 ± 22.0

^* p<0.02 between normal controls and patients

^** p<0.005 between normal controls and patients

^*** p<0.05 between normal controls and patients

Table 3.

Changes of Total WBC, Lymphocytes and Percent of Lymphocytes with Treatment (n = 23)

	WBC (/mm³)	Lymphocytes (/mm³)	Percent (%)
Before treatment	8678 ± 5137	2412 ± 888	33.6 ± 19.6
After treatment	6747 ± 2383	2435 ± 853	36.6 ± 10.1
Before operation (n = 8)	9975 ± 3752	3210 ± 547	36.3 ± 13.7
After operation	6200 ± 2401^*	2446 ± 865	42.2 ± 18.5
Before chemotherapy (n = 15)	8041 ± 5761	1986 ± 728	32.2 ± 22.5
After chemotherapy	7041 ± 2404	2242 ± 737	33.6 ± 14.4

^* p = 0.02 between before and after therapy

Table 4.

T Cell Subsets in Normal Controls and Patients with Lung Cancer

	OKT4(%)	OKT8(%)	OKT4/OKT8
Normal controls (n = 28)	43.3 ± 8.9	29.7 ± 7.7	1.5 ± 1.5
Patients (n = 49)	41.6 ± 12.1	22.6 ± 0.0^*	2.189 ± 1.19^*
	Histology
Squamous (n = 24)	43.7 ± 13.4	23.7 ± 6.9^*	2.036 ± 0.811
Adenocarcinoma (n = 10)	42.0 ± 9.1	20.0 ± 13.7^**	2.810 ± 1.88^**
Small cell cancer (n = 11)	40.9 ± 9.3	22.3 ± 8.3^**	2.09 ± 1.033
Undifferentiated (n = 4)	30.2 ± 14.2^**	23.0 ± 10.5	1.803 ± 1.42
	Stage
NSCLC
Stage I or II (n = 9)	41.3 ± 7.7	23.6 ± 8.8^***	1.969 ± 0.82
Stage III (n = 29)	42.0 ± 14.2	22.4 ± 9.6^***	2.33 ± 1.39^***
SCLC
Limited (n = 3)	49.6 ± 11.8	23.7 ± 8.8	2.961 ± 1.558
Extensive (n = 8)	37.6 ± 6.3	18.6 ± 6.5^***	1.76 ± 0.62

^* p<0.01 between normal controls and patients

^** p<0.05 between normal controls and patients

^*** p<0.02 between normal controls and patients

Table 5.

Changes of T Cell Subsets with Treatment (n = 23)

	OKT4(%)	OKT8(%)	OKT4/OKT8
Patients
Before treatment	44.7 ± 12.7	22.1 ± 6.5^***	2.227 ± 0.77^***
After treatment	39.6 ± 7.2	25.1 ± 10.1	1.756 ± 0.586^*
	Before treatment
Stage
NSCLC Stage I or II (n = 9)	43.1 ± 8.5	21.8 ± 7.9^***	1.972 ± 0.751
Stage III (n = 14)	46.2 ± 14.5	20.4 ± 5.6^***	2.468 ± 0.737^***
SCLC Limited (n = 1)	56.0	25.0	2.24
Extensive (n = 2)	33.5 ± 0.7	27.5 ± 9.1	1.294 ± 0.458
	After treatment
NSCLC Stage I or II	39.5 ± 10.9	30.0 ± 16.0	1.609 ± 0.797
Stage III	39.4 ± 5.8	24.0 ± 6.5^***	1.724 ± 0.405^**
SCLC Limited	40.0	20.0	2.45
Extensive	36.5 ± 2.1	21.5 ± 13.4	2.07 ± 1.195

^* p = 0.024 between before and after treatment

^** p = 0.002 between before and after treatment

^*** p = 0.02 between normal control and treatment

Table 6.

Comparison of Total WBC, Lymphocytes, Percent of Lymphocytes and T Cell Subsets with Treatment According to Mode of Response

	WBC (/mm³)	Lymphocytes (/mm³)	Percent (%)	OKT4 (%)	OKT8 (%)	OKT4/OKT8
Control (n = 28)	7345 ± 1606	2675 ± 456	37.4 ± 7.3	43.3 ± 8.9	29.7 ± 7.7	1.5 ± 1.5
Before treatment
Responder (n = 15)	10587^** ± 6777	2764 ± 795	38.6 ± 18.3	42.2 ± 12.8	22.8 ± 6.6^**	2.071 ± 0.778
Nonresponder (n = 8)	8533 ± 3909	1751 ± 670^***	24.5 ± 19.7^**	49.3 ± 11.8	20.8 ± 6.4^**	2.519 ± 0.708
After treatment
Responder	6446 ± 2394	2448 ± 871	40.0 ± 16.5	40.6 ± 8.0	27.6 ± 11.1	1.654 ± 0.608
Nonresponder	7321 ± 2415	2060 ± 486^**	28.2 ± 12.4^**	37.6 ± 5.3	20.5 ± 5.8^**	1.946 ± 0.526

^* p<0.03 between responder and nonresponder

^** p<0.02 between control and treatment

REFERENCES

1. Roberts HL, Donohoe WTA, Hewitt S, Evans DA. Total lymphocytes in primary bronchial carcinoma. Thorax 32:84. 1977.

2. Kopersztych S, Rezkallah TR, Miki SS, Naspitz CK, Mendes NF. Cell mediated immunity in patients with carcinoma: correlation between clinical stage and immunocompetence. Cancer 38:1149. 1976.

3. Olkowski ZL, McLaren JR, Mansour KA. Immunocompetence of patients with bronchogenic carcinoma. Ann Thoracic Surg 21:546. 1976.

4. Wesselius LJ, David L, Wheaton BS, Wahl LJM, Sherad S, Taylor SA. Lymphocyte subsets in lung cancer. Chest 91:725. 1987.

5. Ginns LC, Goldenheim PD, Miller LG, Burton RC, Gillick L, Colvin RB. T lymphocyte subsets in smoking and lung cancer. Am Rev Resp Dis 126:265. 1982.

6. Krant MJ, Manskopf G, Brandrup CS, Madoff MA. Immunologic alterations in bronchogenic cancer: sequential study. Cancer 21:623. 1968.

7. Dillman RD, Koziol JA, Zavanelli MI, Beauregard JC, Halliburton BL. Immunocompetence in cancer patients: assessment by in vitro stimulation test and quantification of lymphocyte subpopulation. Cancer 53:1484. 1984.

8. Gross RL, Latty A, Williams EA, Newberne PM. Abnormal spontaneous rosette formation and rosette inhibition in lung carcinoma:. New Eng J Med 292:439. 1975.

9. Anthony HM, Kirk JA, Madsen KE, Madson MK, Templeman GH. E and EAC rosetting lymphocytes in patients with carcinoma of bronchus:1, some parameters of the test and its prognostic significance. Clin Exp Immunol 20:29. 1975.

10. Lee KJ, Nam JM, Son KS, Kim JO, Kim SY. T-cell subsets in patients with lung cancer(l). Korean J Tuberc and Resp Dis 35:38. 1987.

11. Costbel U, Bross KJ, Reuter C, Reühle KH, Matthys H. Alterations in immunoregulatory T cell subsets in a cigarette smoker:a phenotypic analysis of bronchoalveolar and blood lymphocytes. Chest 90:39. 1986.

12. Park HS, Sohn HY, Lee H, Ann CM, Lee WY, Kim K. T lymphocyte subsets and its reactivity in bronchogenic carcinoma. Korean J Int Med 31:148. 1986.

13. Jansen HM, Esselink MT, Orie NGM. Cell mediated immune response in patients with bronchial carcinoma. Neth J Med 22:1. 1979.

14. Lichtenstein A, Zighelboim J, Dorey F, Brossman F, Fahey JL. Comparison of immune derangement in patients with different malignancies. Cancer 45:2090. 1980.

15. Dellon AL, Potvin C, Chretinen PB. Thymus dependent lymphocyte levels in bronchognic carcinoma:correlations with histology, clinical stage and clinical course after surgical treatment. Cancer 35:687. 1975.

16. Dellon AL, Potvin C, CHretinen PB. Thymus dependent lymphocyte levels during radiation therapy for bronchogenic and esophgeal carcinoma: correlations with clinical course in responders and nonresponders. Am J Roentgenol Rad Ther Nucl Med 123:501. 1975.

17. Casciato DA, Lowitz BB. Introduction to cancer patients management: 1st ed. Manual of bed side oncology. 1:4. Bouston/Toronto: Little Brown Company, 1983.

18. Eilber FR, Morton DL. Impaired immunologic reactivity and recurrence following cancer surgery. Cancer 25:362. 1970.

19. Lee YN, Sparks FC, Eilber FR, Morton DL. Delayed cutaneous hypersensitivity and peripheral lymphocyte counts in patients with advanced cancer. Cancer 35:748. 1975.

20. Israel L. Cell mediated immunity in lung cancer patients:data, problems and proportions. Cancer chemotherapy Rep Suppl. 4:279. 1973.

21. Israel L, Cros-Decam J, Mugica J. Contribution a l’étude des phénomenès d’immunité cellulaire chez les cancereux pulmonaries:avant traitment palliatif ou chirugical. Poumon et le Couer 24:339. 1968.

22. Anthony HM, Kirk JA, Madsen KE, Mason MK, Templeman GH. E and EAC rosetting lymphocytes in patients with carcinoma of bronchus: II a sequential study of thirty patients:effect of BCG. Clin Exp Immunol 20:41. 1975.

23. Ginns LC, Rogol PR, Murphy M. Extent of squamous cancer of the lung correlates with alterations in circulating T cells. Diag Immunol 1:155. 1983.