# Cortical laminar thicknesses from a number of published experimental studies (see supplement of Schmidt et al. (2017) for details) area L1 L2 L3 L2/3 L4A L4B L4Calpha L4Cbeta L4C L4 L5 L6 L5/6 total_without_L1 total source note FEF 710 180 970 1860 Dombrowski et al. (2001) – Quantitative architecture distinguishes prefrontal cortical systems in the rhesus monkey estimated from Fig. 3. Central FEF=lateral area 8A. Medial FEF=medial area 8A. Lateral FEF= area 45 (Schall et al., 1993) 7a 175 530 695 150 Medalla and Barbas (2006) Diversity of laminar connections linking periarcuate and lateral intraparietal areas depends on cortical structure Fig. 5C 7a Blatt et al. (1990) – Visual receptive field organization and cortico-cortical connections of the lateral intraparietal area (area LIP) in the macaque. Has layer indications but no boundaries. Fig. 12. rough estimates since the layer boundaries were not indicated, just layer labels: L2/3 520 micrometers, L4 140 micrometers STPp see STP data from Rozzi et al. CITv Weller and Steele (1992) Fig. 17 has layer indications but no boundaries for CIT PITv Take from TEO? Weller and Steele (1992) Fig. 3D has layer indications but no boundaries for caudal IT VP schematically shown in Fig. 6 of Maunsell and Van Essen (1983) – The connections of the middle temporal visual area (MT) and their relationship to a cortical hierarchy in the macaque monkey V3A 200 0 520 520 120 Nakamura et al. (2001) – From three-dimensional space vision... Fig. 5B V3A 155 135 Anderson and Martin (2005) – Connection from cortical area V2 to V3A in macaque monkey, Fig. 2 For rough approximation, see also Ungerleider and Desimone (1986) Fig. 2 TF 480 70 190 Suzuki and Amaral (2003) – Perirhinal and parahippocampal cortices of the macaque monkey: cytoarchitectonic and chemoarchitectonic organization estimated from Fig. 14. Where L6 ends is not entirely clear. LIP 170 520 690 155 Medalla and Barbas (2006) Diversity of laminar connections linking periarcuate and lateral intraparietal areas depends on cortical structure, average of Fig. 5A & B See also Cavada and Goldman-Rakic, Multiple visual areas in the posterior parietal cortex of primates, Fig. 3 V4t MIP 125 545 110 100 445 1200 1325 Rozzi et al. (2006) – Cortical connections of the inferior parietal cortical convexity of the macaque monkey estimated from Fig. 11 CITd Weller and Steele (1992) Fig. 17 has layer indications but no boundaries for CIT MSTd see MST data from Rozzi et al. DP Andersen et al. (1990) Corticocortical Connections of Anatomically and Physiologically Defined Subdivisions Within the Inferior Parietal Lobule Fig. 7A has layer boundaries for DP but without a scale bar STPa see STP data from Rozzi et al. MSTl see MST data from Rozzi et al. MT 225 1060 250 210 225 1745 1970 Markov et al. (2013) Anatomy of Hierarchy: Feedforward and Feedback Pathways in Macaque Visual Cortex Estimated from Fig. 8; layer boundaries drawn continuously MT 840 160 240 Cusick et al. (1995) – Chemoarchitectonics and corticocortical terminations within the superior temporal sulcus of the rhesus monkey: evidence for subdivisions of superior temporal polysensory cortex estimated from Fig. 3. Only L4 indicated by name; the other layers by dashes. However, layer names are indicated in the adjacent figure. 46 164 141 572 713 164 234 309 1420 1584 Eggan & Lewis (2007) – Immunocytochemical distribution of the cannabinoid CB1 receptor in the primate neocortex: a regional and laminar analysis Fig. 1 (used 1A. 1B and C show laminar thicknesses of the same areas, which are similar but not identical to 1A ) 46 660 170 550 1380 Dombrowski et al. (2001) – Quantitative architecture distinguishes prefrontal cortical systems in the rhesus monkey estimated from Fig. 3 AITv VIP See Preuss and Goldman-Rakic (1991) – Architectonics of the parietal and temporal association cortex in the strepsirhine primate Galago compared to the anthropoid primate Macaca Fig. 12. for rough approximation, see also Ungerleider and Desimone (1986) Fig. 2 PITd Weller and Steele (1992) Fig. 3D has layer indications but no boundaries for caudal IT VOT take from TEO? V1 122.9 396.9 127.1 211.4 247.5 586 226.3 260.2 1469.4 1592.3 O'Kusky and Colonnier (1982) Table 3; adult values V1 100 340 450 130 140 1060 1160 Rakic et al. (1991) A novel cytoarchitectonic area induced experimentally within the primate visual cortex Control from Table 2. the monkey was 3 months old V2 60 365 125 185 160 835 895 Markov et al. (2013) Anatomy of Hierarchy: Feedforward and Feedback Pathways in Macaque Visual Cortex Fig. 2 V2 110 470 210 150 180 1010 1120 Rakic et al. (1991) A novel cytoarchitectonic area induced experimentally within the primate visual cortex Control from Table 2. The monkey was 3 months old; see Hendry, Fuchs, deBlas & Jones. J. Neurosci. 1990 Fig. 3 for adult V2 Levitt et al. (1995) Connections between the pulvinar complex and cytochrome oxidase-defined compartments in visual area V2 of macaque monkey, Fig. 4A V3 200 1250 250 210 250 1960 2160 Markov et al. (2013) Anatomy of Hierarchy: Feedforward and Feedback Pathways in Macaque Visual Cortex Estimated from Fig. 8; layer boundaries drawn continuously V3 195 285 265 250 800 995 Angelucci et al. (2002) – Circuits for local and global signal integration in primary visual cortex Fig. 4 V4 150 150 700 850 200 200 200 1450 1600 Rockland et al. (1992) – Configuration, in serial reconstruction, of individual axons projecting from area V2 to V4 in the macaque monkey From text on p. 355. See also Anderson et al. (2011), Fig. 2; Distler et al. (1993) Fig. 6C TH 440 0 170 Suzuki and Amaral (2003) – Perirhinal and parahippocampal cortices of the macaque monkey: cytoarchitectonic and chemoarchitectonic organization estimated from Fig. 14. Where L6 ends is not entirely clear. PIP FST MDP PO 215 0 740 740 140 Nakamura et al. (2001) – From three-dimensional space vision to prehensile hand movements: the lateral intraparietal area links the area V3A and the anterior intraparietal area in macaques Fig. 5C; note that V6 and V6A overlap to some extent with PO (Passarelli et al., 2011 – Cortical connections of area V6Av in the macaque...) AITd TE 625 145 131 Suzuki and Amaral (2003) – Perirhinal and parahippocampal cortices of the macaque monkey: cytoarchitectonic and chemoarchitectonic organization Estimated from Fig. 14. Can perhaps be used for CITd, CITv, AITd, AITv (see Tamura and Tanaka, 2001), though CITv and CITd are type 5 and AITd, AITv are type 4 MST 910 210 190 Cusick et al. (1995) – Chemoarchitectonics and corticocortical terminations within the superior temporal sulcus of the rhesus monkey: evidence for subdivisions of superior temporal polysensory cortex estimated from Fig. 3. Only L4 indicated by name; the other layers by dashes. However, layer names are indicated in the adjacent figure. MST Blatt et al. (1990) – Visual receptive field organization and cortico-cortical connections of the lateral intraparietal area (area LIP) in the macaque Fig. 10. rough estimates since the layer boundaries were not indicated, just layer labels: L2/3 730 micrometers, L4 210 micrometers, L5 180 micrometers PG 820 170 220 390 1600 Gregoriou et al. (2006) – Architectonic organization of the inferior parietal convexity of the macaque monkey corresponds roughly to 7a; estimated from Fig. 4 V4 760 150 390 Cusick et al. (1995) – Chemoarchitectonics and corticocortical terminations within the superior temporal sulcus of the rhesus monkey: evidence for subdivisions of superior temporal polysensory cortex estimated from Fig. 4B TPOc 850 225 275 Cusick et al. (1995) – Chemoarchitectonics and corticocortical terminations within the superior temporal sulcus of the rhesus monkey: evidence for subdivisions of superior temporal polysensory cortex estimated from Fig. 5. Appears to correspond approximately to STPp. V1 120 490 110 200 150 110 570 220 120 1400 1520 Felleman et al. (1997) – Cortical connections of area V3 and VP of macaque monkey extrastriate visual cortex estimated from Fig. 7 4 140 880 0 540 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 9. minimal thickness of L6 can also be taken from here 6D 110 780 0 720 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 9. minimal thickness of L6 can also be taken from here 6M 180 640 150 380 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 9. minimal thickness of L6 can also be taken from here 6V 160 720 170 530 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 10. minimal thickness of L6 can also be taken from here PrCO 220 860 220 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 10. minimal thickness of L5+6 can also be taken from here OFO 150 640 220 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 10. minimal thickness of L5+6 can also be taken from here 13L 110 590 155 360 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 12. minimal thickness of L6 can also be taken from here 13M 100 730 130 320 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 12. minimal thickness of L6 can also be taken from here 14L 110 440 150 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 13. minimal thickness of L5+6 can also be taken from here 14VL 200 550 130 190 190 1060 1260 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 13. 14A 170 670 120 270 250 1310 1480 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 13. PL 200 520 0 410 660 1590 1790 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 15 IL 160 840 170 280 340 1630 1790 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 15 MF 150 630 190 240 460 1520 1670 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 15 45 170 720 210 740 1670 1840 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 17. corresponds to lateral FEF 8Ac 150 610 220 330 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 17 8Ar 140 460 140 310 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 17 8Am 190 780 170 300 430 1680 1870 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 17. Corresponds to medial FEF 8Bd 120 790 135 1760 2805 2685 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 18 8Bm 180 620 130 310 1190 2250 2430 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 18 9d 120 740 220 570 800 2330 2450 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 19 9m 160 740 150 500 900 2290 2450 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 19 46dr 185 1080 290 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 20. Assumed the scale bar was 500 micrometers 46d 230 800 250 250 415 1715 1945 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 20. Assumed the scale bar was 500 micrometers 46v 215 715 170 280 290 1455 1670 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 20. Assumed the scale bar was 500 micrometers 46vr 140 690 230 520 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 20. Assumed the scale bar was 500 micrometers 12vl 170 700 180 370 960 2210 2380 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca Estimated from Fig. 21 12orb 170 730 210 320 380 1640 1810 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 21 10 260 960 260 395 835 2450 2710 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 22 46r 180 625 120 180 240 1165 1345 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 22 11 170 700 110 260 330 1400 1570 Preuss and Goldman-Rakic (1991) – Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca estimated from Fig. 22 FEF 195 175 655 830 310 335 315 650 1790 1985 Boussaoud et al. (1990) – Pathways for motion analysis... Fig. 18 PF Rozzi et al. (2006) – Cortical connections of the inferior parietal cortical convexity of the macaque monkey estimated from Fig. 3. Rozzi writes that this is the rostral part of FvE area 7b – not visual. PFG Rozzi et al. (2006) – Cortical connections of the inferior parietal cortical convexity of the macaque monkey estimated from Fig. 3. Rozzi writes that this may correspond to the caudal part of FvE area 7b (but definition is tricky) – not visual. PG Rozzi et al. (2006) – Cortical connections of the inferior parietal cortical convexity of the macaque monkey estimated from Figs 3, 8 and 14. according to Pandya and Seltzer (1982), PG and Opt are both parts of 7a. Rozzi writes that this may be the rostral part of 7a (but definition is tricky). I'm not sure how this is compatible with Max's scheme translation, where Pga corresponds to STPp and STPa. He also translates Ipa to STPp and STPa, but Rozzi et al. State that Ipa is ventral to STPa. Opt Rozzi et al. (2006) – Cortical connections of the inferior parietal cortical convexity of the macaque monkey estimated from Figs 3 and 11. according to Pandya and Seltzer (1982), PG and Opt are both parts of 7a. Rozzi writes that Opt is the caudal part of 7a. LIP 123 486 118 105 536 1245 1368 Rozzi et al. (2006) – Cortical connections of the inferior parietal cortical convexity of the macaque monkey Fig. 8 Pgm Rozzi et al. (2006) – Cortical connections of the inferior parietal cortical convexity of the macaque monkey Fig. 8 MST 227 847 119 131 290 421 1387 1614 Rozzi et al. (2006) – Cortical connections of the inferior parietal cortical convexity of the macaque monkey Fig. 14. See also Figs 8 and 11. STP 70 670 170 437 530 967 1807 1877 Rozzi et al. (2006) – Cortical connections of the inferior parietal cortical convexity of the macaque monkey Fig. 8 Ipa Rozzi et al. (2006) – Cortical connections of the inferior parietal cortical convexity of the macaque monkey Figs 8 and 11. Rozzi: Ipa is the fundal region of the sulcus ventral to STPa. Tepv Rozzi et al. (2006) – Cortical connections of the inferior parietal cortical convexity of the macaque monkey Fig. 8 F7 Rozzi et al. (2006) – Cortical connections of the inferior parietal cortical convexity of the macaque monkey Fig. 8 F5 Rozzi et al. (2006) – Cortical connections of the inferior parietal cortical convexity of the macaque monkey Figs 8, 11 and 14 45 Rozzi et al. (2006) – Cortical connections of the inferior parietal cortical convexity of the macaque monkey Fig. 8 SII Rozzi et al. (2006) – Cortical connections of the inferior parietal cortical convexity of the macaque monkey Figs 11 and 14 23c Rozzi et al. (2006) – Cortical connections of the inferior parietal cortical convexity of the macaque monkey Fig. 11 Tpt Rozzi et al. (2006) – Cortical connections of the inferior parietal cortical convexity of the macaque monkey Fig. 11. 69.2% of Tpt is STPp F2 Rozzi et al. (2006) – Cortical connections of the inferior parietal cortical convexity of the macaque monkey Fig. 11 and 14 46v Rozzi et al. (2006) – Cortical connections of the inferior parietal cortical convexity of the macaque monkey Fig. 11 and 14 Pea Rozzi et al. (2006) – Cortical connections of the inferior parietal cortical convexity of the macaque monkey Fig. 14 Tem Rozzi et al. (2006) – Cortical connections of the inferior parietal cortical convexity of the macaque monkey Fig. 14 F1 Matelli et al. (1991) – Architecture of superior and mesial area 6 and the adjacent cingulate cortex in the macaque monkey F2 Matelli et al. (1991) – Architecture of superior and mesial area 6 and the adjacent cingulate cortex in the macaque monkey F3 Matelli et al. (1991) – Architecture of superior and mesial area 6 and the adjacent cingulate cortex in the macaque monkey F6 Matelli et al. (1991) – Architecture of superior and mesial area 6 and the adjacent cingulate cortex in the macaque monkey F7 Matelli et al. (1991) – Architecture of superior and mesial area 6 and the adjacent cingulate cortex in the macaque monkey 23 Matelli et al. (1991) – Architecture of superior and mesial area 6 and the adjacent cingulate cortex in the macaque monkey 24 Matelli et al. (1991) – Architecture of superior and mesial area 6 and the adjacent cingulate cortex in the macaque monkey TE 164 532 350 Distler et al. (1993) – Cortical connections of inferior temporal area TEO in macaque monkeys Fig. 6D; From this paper: TEO corresponds roughly to PITv and VOT. Tanigawa et al. (1998) – Distribution, morphology, … also has many micrographs of TE with layer indications, but no precise indications of which parts of TE are shown. 3b Preuss and Goldman-Rakic (1991) – Architectonics of the parietal and temporal association cortex in the strepsirhine primate Galago compared to the anthropoid primate Macaca Fig. 7 5 Preuss and Goldman-Rakic (1991) – Architectonics of the parietal and temporal association cortex in the strepsirhine primate Galago compared to the anthropoid primate Macaca Fig. 7 S2 Preuss and Goldman-Rakic (1991) – Architectonics of the parietal and temporal association cortex in the strepsirhine primate Galago compared to the anthropoid primate Macaca Fig. 7 7b Preuss and Goldman-Rakic (1991) – Architectonics of the parietal and temporal association cortex in the strepsirhine primate Galago compared to the anthropoid primate Macaca Fig. 10 7a-l Preuss and Goldman-Rakic (1991) – Architectonics of the parietal and temporal association cortex in the strepsirhine primate Galago compared to the anthropoid primate Macaca Fig. 10 7a-m Preuss and Goldman-Rakic (1991) – Architectonics of the parietal and temporal association cortex in the strepsirhine primate Galago compared to the anthropoid primate Macaca Fig. 10 7op Preuss and Goldman-Rakic (1991) – Architectonics of the parietal and temporal association cortex in the strepsirhine primate Galago compared to the anthropoid primate Macaca Fig. 10 LIP 180 720 170 180 140 1210 1390 Preuss and Goldman-Rakic (1991) – Architectonics of the parietal and temporal association cortex in the strepsirhine primate Galago compared to the anthropoid primate Macaca Fig. 12 VIP 160 740 180 130 100 1150 1310 Preuss and Goldman-Rakic (1991) – Architectonics of the parietal and temporal association cortex in the strepsirhine primate Galago compared to the anthropoid primate Macaca Fig. 12 7m Preuss and Goldman-Rakic (1991) – Architectonics of the parietal and temporal association cortex in the strepsirhine primate Galago compared to the anthropoid primate Macaca Fig. 12 31 Preuss and Goldman-Rakic (1991) – Architectonics of the parietal and temporal association cortex in the strepsirhine primate Galago compared to the anthropoid primate Macaca Fig. 12 Tpt Preuss and Goldman-Rakic (1991) – Architectonics of the parietal and temporal association cortex in the strepsirhine primate Galago compared to the anthropoid primate Macaca Fig. 14 Ipa Preuss and Goldman-Rakic (1991) – Architectonics of the parietal and temporal association cortex in the strepsirhine primate Galago compared to the anthropoid primate Macaca Fig. 14 Tem Preuss and Goldman-Rakic (1991) – Architectonics of the parietal and temporal association cortex in the strepsirhine primate Galago compared to the anthropoid primate Macaca Fig. 14 Tec Preuss and Goldman-Rakic (1991) – Architectonics of the parietal and temporal association cortex in the strepsirhine primate Galago compared to the anthropoid primate Macaca Fig. 14 MT 140 640 210 240 270 1360 1500 Preuss and Goldman-Rakic (1991) – Architectonics of the parietal and temporal association cortex in the strepsirhine primate Galago compared to the anthropoid primate Macaca Fig. 18 TF 270 760 240 700 1700 1970 Preuss and Goldman-Rakic (1991) – Architectonics of the parietal and temporal association cortex in the strepsirhine primate Galago compared to the anthropoid primate Macaca Fig. 18 TH 180 420 150 370 170 1110 1290 Preuss and Goldman-Rakic (1991) – Architectonics of the parietal and temporal association cortex in the strepsirhine primate Galago compared to the anthropoid primate Macaca Fig. 18 V6 162 152 466 618 152 155 Passarelli et al. (2011) – Cortical connections of area V6Av in the macaque: a visual-input node to the eye/hand coordination system Fig. 4. Area definition according to Galletti. Could use average of V6, V6Av and V6Ad for PO? V6Av 145 124 407 531 221 214 455 669 1421 1566 Passarelli et al. (2011) – Cortical connections of area V6Av in the macaque: a visual-input node to the eye/hand coordination system Fig. 4. Area definition according to Galletti. V6Ad 114 162 476 638 203 166 410 576 1417 1531 Passarelli et al. (2011) – Cortical connections of area V6Av in the macaque: a visual-input node to the eye/hand coordination system Fig. 4. Area definition according to Galletti. 46 130 425 85 350 860 990 Petrides and Pandya (1999) – Dorsolateral prefrontal cortex: comparative cytoarchitectonic analysis in the human and the macaque brain and corticocortical connection patterns Fig. 7 7m Eggan & Lewis (2007) – Immunocytochemical distribution of the cannabinoid CB1 receptor in the primate neocortex: a regional and laminar analysis Fig. 4 FST? Eggan & Lewis (2007) – Immunocytochemical distribution of the cannabinoid CB1 receptor in the primate neocortex: a regional and laminar analysis Fig. 5C V1 59 173 222 395 62 155 150 83 450 173 181 1200 1259 Eggan & Lewis (2007) – Immunocytochemical distribution of the cannabinoid CB1 receptor in the primate neocortex: a regional and laminar analysis Fig. 5B upper bank of rostral STS Saleem et al. (2000) – Connections between anterior inferotemporal cortex and superior temporal sulcus regions in the macaque monkey This may correspond to STPa. Fig. 6: camera lucida drawings with layer boundaries; Fig. 7: layer indications without boundaries lower bank of middle STS Saleem et al. (2000) – Connections between anterior inferotemporal cortex and superior temporal sulcus regions in the macaque monkey Fig. 6: camera lucida drawings with layer boundaries; Fig. 7: layer indications without boundaries lower bank of rostral STS Saleem et al. (2000) – Connections between anterior inferotemporal cortex and superior temporal sulcus regions in the macaque monkey Fig. 7, layer indications without boundaries STP 121 182 403 585 262 371 256 627 1474 1595 Cipolloni and Pandya (1989) – Connectional analysis of the ipsilateral and contralateral afferent neurons of the superior temporal region in the rhesus monkey Fig. 2 8/FEF Gerbella et al. (2007) – Multimodal architectonic subdivision of the caudal ventrolateral prefrontal cortex of the macaque monkey Fig. 8 45B Gerbella et al. (2007) – Multimodal architectonic subdivision of the caudal ventrolateral prefrontal cortex of the macaque monkey Fig. 8 45A Gerbella et al. (2007) – Multimodal architectonic subdivision of the caudal ventrolateral prefrontal cortex of the macaque monkey Fig. 8 8r Gerbella et al. (2007) – Multimodal architectonic subdivision of the caudal ventrolateral prefrontal cortex of the macaque monkey Fig. 8 46v Gerbella et al. (2007) – Multimodal architectonic subdivision of the caudal ventrolateral prefrontal cortex of the macaque monkey Fig. 8 12 Gerbella et al. (2007) – Multimodal architectonic subdivision of the caudal ventrolateral prefrontal cortex of the macaque monkey Fig. 8 FST 354 232 390 622 122 384 1128 1482 Lavenex et al. (2002) – Perirhinal and parahippocampal cortices of the macaque monkey: projections to the neocortex Fig. 15, called STSf (floor of superior temporal sulcus) in the paper TE Lavenex et al. (2002) – Perirhinal and parahippocampal cortices of the macaque monkey: projections to the neocortex Fig. 15. Atlas: Von Bonin & Bailey, 1947 TEO 128 183 274 557 128 268 274 542 1227 1355 Lavenex et al. (2002) – Perirhinal and parahippocampal cortices of the macaque monkey: projections to the neocortex Fig. 15. Atlas: Von Bonin & Bailey, 1947 STG Lavenex et al. (2002) – Perirhinal and parahippocampal cortices of the macaque monkey: projections to the neocortex Fig. 16 STSd Lavenex et al. (2002) – Perirhinal and parahippocampal cortices of the macaque monkey: projections to the neocortex Fig. 16 24 Lavenex et al. (2002) – Perirhinal and parahippocampal cortices of the macaque monkey: projections to the neocortex Fig. 16 23/30 Lavenex et al. (2002) – Perirhinal and parahippocampal cortices of the macaque monkey: projections to the neocortex Fig. 16 7 Lavenex et al. (2002) – Perirhinal and parahippocampal cortices of the macaque monkey: projections to the neocortex Fig. 16 11 Lavenex et al. (2002) – Perirhinal and parahippocampal cortices of the macaque monkey: projections to the neocortex Fig. 17 13 Lavenex et al. (2002) – Perirhinal and parahippocampal cortices of the macaque monkey: projections to the neocortex Fig. 17 46 Lavenex et al. (2002) – Perirhinal and parahippocampal cortices of the macaque monkey: projections to the neocortex Fig. 17 Ig Lavenex et al. (2002) – Perirhinal and parahippocampal cortices of the macaque monkey: projections to the neocortex Fig. 17 Pi Lavenex et al. (2002) – Perirhinal and parahippocampal cortices of the macaque monkey: projections to the neocortex Fig. 17